(* index of the greatest Cic.Meta created - TODO: find a better way! *)
let maxmeta = ref 0;;
+(* varbiables controlling the search-space *)
+let maxdepth = ref 3;;
+let maxwidth = ref 3;;
+
type result =
| ParamodulationFailure
- | ParamodulationSuccess of Inference.equality option * environment
+ | ParamodulationSuccess of Inference.proof option * environment
;;
module EqualitySet = Set.Make(OrderedEquality);;
-let select env passive (active, _) =
+let select env goals passive (active, _) =
processed_clauses := !processed_clauses + 1;
+
+ let goal =
+ match (List.rev goals) with (_, goal::_)::_ -> goal | _ -> assert false
+ in
let (neg_list, neg_set), (pos_list, pos_set), passive_table = passive in
let remove eq l =
let cardinality map =
TermMap.fold (fun k v res -> res + v) map 0
in
- match active with
- | (Negative, e)::_ ->
- let symbols = symbols_of_equality e in
+(* match active with *)
+(* | (Negative, e)::_ -> *)
+(* let symbols = symbols_of_equality e in *)
+ let symbols =
+ let _, _, term = goal in
+ symbols_of_term term
+ in
let card = cardinality symbols in
let foldfun k v (r1, r2) =
if TermMap.mem k symbols then
(([], neg_set),
(remove current pos_list, EqualitySet.remove current pos_set),
passive_table)
- | _ ->
- let current = EqualitySet.min_elt pos_set in
- let passive_table =
- Indexing.remove_index passive_table current
-(* if !use_fullred then Indexing.remove_index passive_table current *)
-(* else passive_table *)
- in
- let passive =
- (neg_list, neg_set),
- (remove current pos_list, EqualitySet.remove current pos_set),
- passive_table
- in
- (Positive, current), passive
+(* | _ -> *)
+(* let current = EqualitySet.min_elt pos_set in *)
+(* let passive_table = *)
+(* Indexing.remove_index passive_table current *)
+(* (\* if !use_fullred then Indexing.remove_index passive_table current *\) *)
+(* (\* else passive_table *\) *)
+(* in *)
+(* let passive = *)
+(* (neg_list, neg_set), *)
+(* (remove current pos_list, EqualitySet.remove current pos_set), *)
+(* passive_table *)
+(* in *)
+(* (Positive, current), passive *)
)
| _ ->
symbols_counter := !symbols_ratio;
in
let in_weight = round (howmany *. ratio /. (ratio +. 1.))
and in_age = round (howmany /. (ratio +. 1.)) in
- debug_print (lazy (Printf.sprintf "in_weight: %d, in_age: %d\n" in_weight in_age));
+ debug_print
+ (lazy (Printf.sprintf "in_weight: %d, in_age: %d\n" in_weight in_age));
let symbols, card =
match active with
| (Negative, e)::_ ->
let demodulate table current =
let newmeta, newcurrent =
- Indexing.demodulation !maxmeta env table sign current in
+ Indexing.demodulation_equality !maxmeta env table sign current in
maxmeta := newmeta;
if is_identity env newcurrent then
if sign = Negative then Some (sign, newcurrent)
let demodulate sign table target =
let newmeta, newtarget =
- Indexing.demodulation !maxmeta env table sign target in
+ Indexing.demodulation_equality !maxmeta env table sign target in
maxmeta := newmeta;
newtarget
in
let subs =
match passive_table with
| None ->
- (fun e -> not (Indexing.subsumption env active_table e))
+ (fun e -> not (fst (Indexing.subsumption env active_table e)))
| Some passive_table ->
- (fun e -> not ((Indexing.subsumption env active_table e) ||
- (Indexing.subsumption env passive_table e)))
+ (fun e -> not ((fst (Indexing.subsumption env active_table e)) ||
+ (fst (Indexing.subsumption env passive_table e))))
in
let t1 = Unix.gettimeofday () in
;;
-let rec given_clause env passive active =
+let simplify_goal env goal ?passive (active_list, active_table) =
+ let pl, passive_table =
+ match passive with
+ | None -> [], None
+ | Some ((pn, _), (pp, _), pt) ->
+ let pn = List.map (fun e -> (Negative, e)) pn
+ and pp = List.map (fun e -> (Positive, e)) pp in
+ pn @ pp, Some pt
+ in
+ let all = if pl = [] then active_list else active_list @ pl in
+
+ let demodulate table goal =
+ let newmeta, newgoal =
+ Indexing.demodulation_goal !maxmeta env table goal in
+ maxmeta := newmeta;
+ newgoal
+ in
+ let goal =
+ match passive_table with
+ | None -> demodulate active_table goal
+ | Some passive_table ->
+ let goal = demodulate active_table goal in
+ demodulate passive_table goal
+ in
+ let _ =
+ let p, _, t = goal in
+ debug_print
+ (lazy
+ (Printf.sprintf "Goal after demodulation: %s, %s"
+ (string_of_proof p) (CicPp.ppterm t)))
+ in
+ goal
+;;
+
+
+let simplify_goals env goals ?passive active =
+ List.map
+ (fun (d, gl) ->
+ let gl = List.map (fun g -> simplify_goal env g ?passive active) gl in
+ d, gl)
+ goals
+;;
+
+
+let simplify_theorems env theorems ?passive (active_list, active_table) =
+ let pl, passive_table =
+ match passive with
+ | None -> [], None
+ | Some ((pn, _), (pp, _), pt) ->
+ let pn = List.map (fun e -> (Negative, e)) pn
+ and pp = List.map (fun e -> (Positive, e)) pp in
+ pn @ pp, Some pt
+ in
+ let all = if pl = [] then active_list else active_list @ pl in
+
+ let demodulate table theorem =
+ let newmeta, newthm =
+ Indexing.demodulation_theorem !maxmeta env table theorem in
+ maxmeta := newmeta;
+ newthm
+ in
+ match passive_table with
+ | None -> List.map (demodulate active_table) theorems
+ | Some passive_table ->
+ let theorems = List.map (demodulate active_table) theorems in
+ List.map (demodulate passive_table) theorems
+;;
+
+
+let apply_equality_to_goal env equality goal =
+ let module C = Cic in
+ let module HL = HelmLibraryObjects in
+ let module I = Inference in
+ let metasenv, context, ugraph = env in
+ let _, proof, (ty, left, right, _), metas, args = equality in
+ let eqterm = C.Appl [C.MutInd (HL.Logic.eq_URI, 0, []); ty; left; right] in
+ let gproof, gmetas, gterm = goal in
+ try
+ let subst, metasenv', _ =
+ let menv = metasenv @ metas @ gmetas in
+ Inference.unification menv context eqterm gterm ugraph
+ in
+ let newproof =
+ match proof with
+ | I.BasicProof t -> I.BasicProof (CicMetaSubst.apply_subst subst t)
+ | I.ProofBlock (s, uri, nt, t, pe, p) ->
+ I.ProofBlock (subst @ s, uri, nt, t, pe, p)
+ | _ -> assert false
+ in
+ let newgproof =
+ let rec repl = function
+ | I.ProofGoalBlock (_, gp) -> I.ProofGoalBlock (newproof, gp)
+ | I.NoProof -> newproof
+ | I.BasicProof p -> newproof
+ | I.SubProof (t, i, p) -> I.SubProof (t, i, repl p)
+ | _ -> assert false
+ in
+ repl gproof
+ in
+ true, subst, newgproof
+ with CicUnification.UnificationFailure _ ->
+ false, [], I.NoProof
+;;
+
+
+(*
+let apply_to_goal env theorems active (depth, goals) =
+ let _ =
+ debug_print ("apply_to_goal: " ^ (string_of_int (List.length goals)))
+ in
+ let metasenv, context, ugraph = env in
+ let goal = List.hd goals in
+ let proof, metas, term = goal in
+(* debug_print *)
+(* (Printf.sprintf "apply_to_goal with goal: %s" (CicPp.ppterm term)); *)
+ let newmeta = CicMkImplicit.new_meta metasenv [] in
+ let metasenv = (newmeta, context, term)::metasenv @ metas in
+ let irl = CicMkImplicit.identity_relocation_list_for_metavariable context in
+ let status =
+ ((None, metasenv, Cic.Meta (newmeta, irl), term), newmeta)
+ in
+ let rec aux = function
+ | [] -> false, [] (* goals *) (* None *)
+ | (theorem, thmty, _)::tl ->
+ try
+ let subst_in, (newproof, newgoals) =
+ PrimitiveTactics.apply_tac_verbose ~term:theorem status
+ in
+ if newgoals = [] then
+ let _, _, p, _ = newproof in
+ let newp =
+ let rec repl = function
+ | Inference.ProofGoalBlock (_, gp) ->
+ Inference.ProofGoalBlock (Inference.BasicProof p, gp)
+ | Inference.NoProof -> Inference.BasicProof p
+ | Inference.BasicProof _ -> Inference.BasicProof p
+ | Inference.SubProof (t, i, p2) ->
+ Inference.SubProof (t, i, repl p2)
+ | _ -> assert false
+ in
+ repl proof
+ in
+ true, [[newp, metas, term]] (* Some newp *)
+ else if List.length newgoals = 1 then
+ let _, menv, p, _ = newproof in
+ let irl =
+ CicMkImplicit.identity_relocation_list_for_metavariable context
+ in
+ let goals =
+ List.map
+ (fun i ->
+ let _, _, ty = CicUtil.lookup_meta i menv in
+ let proof =
+ Inference.SubProof
+ (p, i, Inference.BasicProof (Cic.Meta (i, irl)))
+ in (proof, menv, ty))
+ newgoals
+ in
+ let res, others = aux tl in
+ if res then (true, others) else (false, goals::others)
+ else
+ aux tl
+ with ProofEngineTypes.Fail msg ->
+ (* debug_print ("FAIL!!:" ^ msg); *)
+ aux tl
+ in
+ let r, l =
+ if Inference.term_is_equality term then
+ let rec appleq = function
+ | [] -> false, []
+ | (Positive, equality)::tl ->
+ let ok, _, newproof = apply_equality_to_goal env equality goal in
+ if ok then true, [(depth, [newproof, metas, term])] else appleq tl
+ | _::tl -> appleq tl
+ in
+ let al, _ = active in
+ appleq al
+ else
+ false, []
+ in
+ if r = true then r, l else
+ let r, l = aux theorems in
+ if r = true then
+ r, List.map (fun l -> (depth+1, l)) l
+ else
+ r, (depth, goals)::(List.map (fun l -> (depth+1, l)) l)
+;;
+*)
+
+
+let new_meta () =
+ incr maxmeta; !maxmeta
+;;
+
+
+let apply_to_goal env theorems active goal =
+ let metasenv, context, ugraph = env in
+ let proof, metas, term = goal in
+ debug_print
+ (lazy
+ (Printf.sprintf "apply_to_goal with goal: %s, %s"
+ (string_of_proof proof) (CicPp.ppterm term)));
+ let status =
+ let irl =
+ CicMkImplicit.identity_relocation_list_for_metavariable context in
+ let proof', newmeta =
+ let rec get_meta = function
+ | SubProof (t, i, _) -> t, i
+ | ProofGoalBlock (_, p) -> get_meta p
+ | _ ->
+ let n = new_meta () in (* CicMkImplicit.new_meta metasenv [] in *)
+ Cic.Meta (n, irl), n
+ in
+ get_meta proof
+ in
+(* let newmeta = CicMkImplicit.new_meta metasenv [] in *)
+ let metasenv = (newmeta, context, term)::metasenv @ metas in
+ ((None, metasenv, Cic.Meta (newmeta, irl), term), newmeta)
+(* ((None, metasenv, proof', term), newmeta) *)
+ in
+ let rec aux = function
+ | [] -> `No (* , [], [] *)
+ | (theorem, thmty, _)::tl ->
+ try
+ let subst, (newproof, newgoals) =
+ PrimitiveTactics.apply_tac_verbose_with_subst ~term:theorem status
+ in
+ if newgoals = [] then
+ let _, _, p, _ = newproof in
+ let newp =
+ let rec repl = function
+ | Inference.ProofGoalBlock (_, gp) ->
+ Inference.ProofGoalBlock (Inference.BasicProof p, gp)
+ | Inference.NoProof -> Inference.BasicProof p
+ | Inference.BasicProof _ -> Inference.BasicProof p
+ | Inference.SubProof (t, i, p2) ->
+ Inference.SubProof (t, i, repl p2)
+ | _ -> assert false
+ in
+ repl proof
+ in
+ let _, m = status in
+ let subst = List.filter (fun (i, _) -> i = m) subst in
+(* debug_print *)
+(* (lazy *)
+(* (Printf.sprintf "m = %d\nsubst = %s\n" *)
+(* m (print_subst subst))); *)
+ `Ok (subst, [newp, metas, term])
+ else
+ let _, menv, p, _ = newproof in
+ let irl =
+ CicMkImplicit.identity_relocation_list_for_metavariable context
+ in
+ let goals =
+ List.map
+ (fun i ->
+ let _, _, ty = CicUtil.lookup_meta i menv in
+ let p' =
+ let rec gp = function
+ | SubProof (t, i, p) ->
+ SubProof (t, i, gp p)
+ | ProofGoalBlock (sp1, sp2) ->
+(* SubProof (p, i, sp) *)
+ ProofGoalBlock (sp1, gp sp2)
+(* gp sp *)
+ | BasicProof _
+ | NoProof ->
+ SubProof (p, i, BasicProof (Cic.Meta (i, irl)))
+ | ProofSymBlock (s, sp) ->
+ ProofSymBlock (s, gp sp)
+ | ProofBlock (s, u, nt, t, pe, sp) ->
+ ProofBlock (s, u, nt, t, pe, gp sp)
+(* | _ -> assert false *)
+ in gp proof
+ in
+ debug_print
+ (lazy
+ (Printf.sprintf "new sub goal: %s, %s"
+ (string_of_proof p') (CicPp.ppterm ty)));
+ (p', menv, ty))
+ newgoals
+ in
+(* debug_print *)
+(* (lazy *)
+(* (Printf.sprintf "\nGoOn with subst: %s" (print_subst subst))); *)
+ let best = aux tl in
+ match best with
+ | `Ok (_, _) -> best
+ | `No -> `GoOn ([subst, goals])
+ | `GoOn sl(* , subst', goals' *) ->
+(* if (List.length goals') < (List.length goals) then best *)
+(* else `GoOn, subst, goals *)
+ `GoOn ((subst, goals)::sl)
+ with ProofEngineTypes.Fail msg ->
+ aux tl
+ in
+ let r, s, l =
+ if Inference.term_is_equality term then
+ let rec appleq = function
+ | [] -> false, [], []
+ | (Positive, equality)::tl ->
+ let ok, s, newproof = apply_equality_to_goal env equality goal in
+ if ok then true, s, [newproof, metas, term] else appleq tl
+ | _::tl -> appleq tl
+ in
+ let al, _ = active in
+ appleq al
+ else
+ false, [], []
+ in
+ if r = true then `Ok (s, l) else aux theorems
+;;
+
+
+let apply_to_goal_conj env theorems active (depth, goals) =
+ let rec aux = function
+ | goal::tl ->
+ let propagate_subst subst (proof, metas, term) =
+ debug_print
+ (lazy
+ (Printf.sprintf "\npropagate_subst:\n%s\n%s, %s\n"
+ (print_subst subst) (string_of_proof proof)
+ (CicPp.ppterm term)));
+ let rec repl = function
+ | NoProof -> NoProof
+ | BasicProof t ->
+ BasicProof (CicMetaSubst.apply_subst subst t)
+ | ProofGoalBlock (p, pb) ->
+ debug_print (lazy "HERE");
+ let pb' = repl pb in
+ ProofGoalBlock (p, pb')
+ | SubProof (t, i, p) ->
+ let t' = CicMetaSubst.apply_subst subst t in
+ debug_print
+ (lazy
+ (Printf.sprintf
+ "SubProof %d\nt = %s\nsubst = %s\nt' = %s\n"
+ i (CicPp.ppterm t) (print_subst subst)
+ (CicPp.ppterm t')));
+ let p = repl p in
+ SubProof (t', i, p)
+ | ProofSymBlock (ens, p) -> ProofSymBlock (ens, repl p)
+ | ProofBlock (s, u, nty, t, pe, p) ->
+ ProofBlock (subst @ s, u, nty, t, pe, p)
+ in (repl proof, metas, term)
+ in
+ let r = apply_to_goal env theorems active goal in (
+ match r with
+ | `No -> `No (depth, goals)
+ | `GoOn sl (* (subst, gl) *) ->
+(* let tl = List.map (propagate_subst subst) tl in *)
+ debug_print (lazy "GO ON!!!");
+ let l =
+ List.map
+ (fun (s, gl) ->
+ (depth+1, gl @ (List.map (propagate_subst s) tl))) sl
+ in
+ debug_print
+ (lazy
+ (Printf.sprintf "%s\n"
+ (String.concat "; "
+ (List.map
+ (fun (s, gl) ->
+ (Printf.sprintf "[%s]"
+ (String.concat "; "
+ (List.map
+ (fun (p, _, g) ->
+ (Printf.sprintf "<%s, %s>"
+ (string_of_proof p)
+ (CicPp.ppterm g))) gl)))) l))));
+ `GoOn l (* (depth+1, gl @ tl) *)
+ | `Ok (subst, gl) ->
+ if tl = [] then
+(* let _ = *)
+(* let p, _, t = List.hd gl in *)
+(* debug_print *)
+(* (lazy *)
+(* (Printf.sprintf "OK: %s, %s\n" *)
+(* (string_of_proof p) (CicPp.ppterm t))) *)
+(* in *)
+ `Ok (depth, gl)
+ else
+ let p, _, _ = List.hd gl in
+ let subproof =
+ let rec repl = function
+ | SubProof (_, _, p) -> repl p
+ | ProofGoalBlock (p1, p2) ->
+ ProofGoalBlock (repl p1, repl p2)
+ | p -> p
+ in
+ build_proof_term (repl p)
+ in
+ let i =
+ let rec get_meta = function
+ | SubProof (_, i, p) -> max i (get_meta p)
+ | ProofGoalBlock (_, p) -> get_meta p
+ | _ -> -1 (* assert false *)
+ in
+ get_meta p
+ in
+ let subst =
+ let _, (context, _, _) = List.hd subst in
+ [i, (context, subproof, Cic.Implicit None)]
+ in
+ let tl = List.map (propagate_subst subst) tl in
+ `GoOn ([depth+1, tl])
+ )
+ | _ -> assert false
+ in
+ debug_print
+ (lazy
+ (Printf.sprintf "apply_to_goal_conj (%d, [%s])"
+ depth
+ (String.concat "; "
+ (List.map (fun (_, _, t) -> CicPp.ppterm t) goals))));
+ if depth > !maxdepth || (List.length goals) > !maxwidth then (
+ debug_print
+ (lazy (Printf.sprintf "Pruning because depth = %d, width = %d"
+ depth (List.length goals)));
+ `No (depth, goals)
+ ) else
+ aux goals
+;;
+
+
+module OrderedGoals = struct
+ type t = int * (Inference.proof * Cic.metasenv * Cic.term) list
+
+ let compare g1 g2 =
+ let d1, l1 = g1
+ and d2, l2 = g2 in
+ let r = d2 - d1 in
+ if r <> 0 then r
+ else let r = (List.length l1) - (List.length l2) in
+ if r <> 0 then r
+ else
+ let res = ref 0 in
+ let _ =
+ List.exists2
+ (fun (_, _, t1) (_, _, t2) ->
+ let r = Pervasives.compare t1 t2 in
+ if r <> 0 then (
+ res := r;
+ true
+ ) else
+ false) l1 l2
+ in !res
+(* let res = Pervasives.compare g1 g2 in *)
+(* let _ = *)
+(* let print_goals (d, gl) = *)
+(* let gl' = List.map (fun (_, _, t) -> CicPp.ppterm t) gl in *)
+(* Printf.sprintf "%d, [%s]" d (String.concat "; " gl') *)
+(* in *)
+(* debug_print *)
+(* (lazy *)
+(* (Printf.sprintf "comparing g1:%s and g2:%s, res: %d\n" *)
+(* (print_goals g1) (print_goals g2) res)) *)
+(* in *)
+(* res *)
+end
+
+module GoalsSet = Set.Make(OrderedGoals);;
+
+
+exception SearchSpaceOver;;
+
+
+let apply_to_goals env is_passive_empty theorems active goals =
+ debug_print (lazy "\n\n\tapply_to_goals\n\n");
+ let add_to set goals =
+ List.fold_left (fun s g -> GoalsSet.add g s) set goals
+ in
+ let rec aux set = function
+ | [] ->
+ debug_print (lazy "HERE!!!");
+ if is_passive_empty then raise SearchSpaceOver else false, set
+ | goals::tl ->
+ let res = apply_to_goal_conj env theorems active goals in
+ match res with
+ | `Ok newgoals ->
+ let _ =
+ let d, p, t =
+ match newgoals with
+ | (d, (p, _, t)::_) -> d, p, t
+ | _ -> assert false
+ in
+ debug_print
+ (lazy
+ (Printf.sprintf "\nOK!!!!\ndepth: %d\nProof: %s\ngoal: %s\n"
+ d (string_of_proof p) (CicPp.ppterm t)))
+ in
+ true, GoalsSet.singleton newgoals
+ | `GoOn newgoals ->
+ let print_set set msg =
+ debug_print
+ (lazy
+ (Printf.sprintf "%s:\n%s" msg
+ (String.concat "\n"
+ (GoalsSet.fold
+ (fun (d, gl) l ->
+ let gl' =
+ List.map (fun (_, _, t) -> CicPp.ppterm t) gl
+ in
+ let s =
+ Printf.sprintf "%d, [%s]" d
+ (String.concat "; " gl')
+ in
+ s::l) set []))))
+ in
+ let set = add_to set (goals::tl) in
+(* print_set set "SET BEFORE"; *)
+ let n = GoalsSet.cardinal set in
+ let set = add_to set newgoals in
+(* print_set set "SET AFTER"; *)
+ let m = GoalsSet.cardinal set in
+(* if n < m then *)
+ false, set
+(* else *)
+(* let _ = print_set set "SET didn't change" in *)
+(* aux set tl *)
+ | `No newgoals ->
+ aux set tl
+(* let set = add_to set (newgoals::goals::tl) in *)
+(* let res, set = aux set tl in *)
+(* res, set *)
+ in
+ let n = List.length goals in
+ let res, goals = aux (add_to GoalsSet.empty goals) goals in
+ let goals = GoalsSet.elements goals in
+ debug_print (lazy "\n\tapply_to_goals end\n");
+ let m = List.length goals in
+ if m = n && is_passive_empty then
+ raise SearchSpaceOver
+ else
+ res, goals
+;;
+
+
+let rec given_clause env goals theorems passive active =
let time1 = Unix.gettimeofday () in
let selection_estimate = get_selection_estimate () in
passive
else if !elapsed_time > !time_limit then (
debug_print (lazy (Printf.sprintf "Time limit (%.2f) reached: %.2f\n"
- !time_limit !elapsed_time));
+ !time_limit !elapsed_time));
make_passive [] []
) else if kept > selection_estimate then (
- debug_print (lazy (Printf.sprintf ("Too many passive equalities: pruning..." ^^
- "(kept: %d, selection_estimate: %d)\n")
- kept selection_estimate));
+ debug_print
+ (lazy (Printf.sprintf ("Too many passive equalities: pruning..." ^^
+ "(kept: %d, selection_estimate: %d)\n")
+ kept selection_estimate));
prune_passive selection_estimate active passive
) else
passive
kept_clauses := (size_of_passive passive) + (size_of_active active);
- match passive_is_empty passive with
- | true -> ParamodulationFailure
- | false ->
- let (sign, current), passive = select env passive active in
- let time1 = Unix.gettimeofday () in
- let res = forward_simplify env (sign, current) ~passive active in
- let time2 = Unix.gettimeofday () in
- forward_simpl_time := !forward_simpl_time +. (time2 -. time1);
- match res with
- | None ->
- given_clause env passive active
- | Some (sign, current) ->
- if (sign = Negative) && (is_identity env current) then (
- debug_print (lazy (Printf.sprintf "OK!!! %s %s" (string_of_sign sign)
- (string_of_equality ~env current)));
- ParamodulationSuccess (Some current, env)
- ) else (
- debug_print (lazy "\n================================================");
- debug_print (lazy (Printf.sprintf "selected: %s %s"
- (string_of_sign sign)
+(* let refl_equal = *)
+(* CicUtil.term_of_uri *)
+(* (UriManager.uri_of_string "cic:/Coq/Init/Logic/eq.ind#xpointer(1/1/1)") *)
+(* in *)
+ let goals = simplify_goals env goals active in
+ let theorems = simplify_theorems env theorems active in
+ let is_passive_empty = passive_is_empty passive in
+ try
+ let ok, goals = apply_to_goals env is_passive_empty theorems active goals in
+ if ok then
+ let proof =
+ match goals with
+ | (_, [proof, _, _])::_ -> Some proof
+ | _ -> assert false
+ in
+ ParamodulationSuccess (proof, env)
+ else
+ match is_passive_empty (* passive_is_empty passive *) with
+ | true -> (* ParamodulationFailure *)
+ given_clause env goals theorems passive active
+ | false ->
+ let (sign, current), passive = select env goals passive active in
+ let time1 = Unix.gettimeofday () in
+ let res = forward_simplify env (sign, current) ~passive active in
+ let time2 = Unix.gettimeofday () in
+ forward_simpl_time := !forward_simpl_time +. (time2 -. time1);
+ match res with
+ | None ->
+ given_clause env goals theorems passive active
+ | Some (sign, current) ->
+ if (sign = Negative) && (is_identity env current) then (
+ debug_print
+ (lazy (Printf.sprintf "OK!!! %s %s" (string_of_sign sign)
(string_of_equality ~env current)));
-
- let t1 = Unix.gettimeofday () in
- let new' = infer env sign current active in
- let t2 = Unix.gettimeofday () in
- infer_time := !infer_time +. (t2 -. t1);
-
- let res, goal = contains_empty env new' in
- if res then
- ParamodulationSuccess (goal, env)
- else
- let t1 = Unix.gettimeofday () in
- let new' = forward_simplify_new env new' (* ~passive *) active in
- let t2 = Unix.gettimeofday () in
- let _ =
- forward_simpl_new_time := !forward_simpl_new_time +. (t2 -. t1)
- in
- let active =
- match sign with
- | Negative -> active
- | Positive ->
- let t1 = Unix.gettimeofday () in
- let active, _, newa, _ =
- backward_simplify env ([], [current]) active
- in
- let t2 = Unix.gettimeofday () in
- backward_simpl_time := !backward_simpl_time +. (t2 -. t1);
- match newa with
- | None -> active
- | Some (n, p) ->
- let al, tbl = active in
- let nn = List.map (fun e -> Negative, e) n in
- let pp, tbl =
- List.fold_right
- (fun e (l, t) ->
- (Positive, e)::l,
- Indexing.index tbl e)
- p ([], tbl)
+ let _, proof, _, _, _ = current in
+ ParamodulationSuccess (Some proof (* current *), env)
+ ) else (
+ debug_print
+ (lazy "\n================================================");
+ debug_print (lazy (Printf.sprintf "selected: %s %s"
+ (string_of_sign sign)
+ (string_of_equality ~env current)));
+
+ let t1 = Unix.gettimeofday () in
+ let new' = infer env sign current active in
+ let t2 = Unix.gettimeofday () in
+ infer_time := !infer_time +. (t2 -. t1);
+
+ let res, goal' = contains_empty env new' in
+ if res then
+ let proof =
+ match goal' with
+ | Some goal -> let _, proof, _, _, _ = goal in Some proof
+ | None -> None
+ in
+ ParamodulationSuccess (proof (* goal *), env)
+ else
+ let t1 = Unix.gettimeofday () in
+ let new' = forward_simplify_new env new' active in
+ let t2 = Unix.gettimeofday () in
+ let _ =
+ forward_simpl_new_time :=
+ !forward_simpl_new_time +. (t2 -. t1)
+ in
+ let active =
+ match sign with
+ | Negative -> active
+ | Positive ->
+ let t1 = Unix.gettimeofday () in
+ let active, _, newa, _ =
+ backward_simplify env ([], [current]) active
in
- nn @ al @ pp, tbl
- in
+ let t2 = Unix.gettimeofday () in
+ backward_simpl_time :=
+ !backward_simpl_time +. (t2 -. t1);
+ match newa with
+ | None -> active
+ | Some (n, p) ->
+ let al, tbl = active in
+ let nn = List.map (fun e -> Negative, e) n in
+ let pp, tbl =
+ List.fold_right
+ (fun e (l, t) ->
+ (Positive, e)::l,
+ Indexing.index tbl e)
+ p ([], tbl)
+ in
+ nn @ al @ pp, tbl
+ in
(* let _ = *)
(* Printf.printf "active:\n%s\n" *)
(* (String.concat "\n" *)
(* (string_of_equality ~env e)) pos))); *)
(* print_newline (); *)
(* in *)
- match contains_empty env new' with
- | false, _ ->
- let active =
- let al, tbl = active in
- match sign with
- | Negative -> (sign, current)::al, tbl
- | Positive ->
- al @ [(sign, current)], Indexing.index tbl current
- in
- let passive = add_to_passive passive new' in
- let (_, ns), (_, ps), _ = passive in
+ match contains_empty env new' with
+ | false, _ ->
+ let active =
+ let al, tbl = active in
+ match sign with
+ | Negative -> (sign, current)::al, tbl
+ | Positive ->
+ al @ [(sign, current)], Indexing.index tbl 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 ps)))); *)
(* print_newline (); *)
- given_clause env passive active
- | true, goal ->
- ParamodulationSuccess (goal, env)
- )
+ given_clause env goals theorems passive active
+ | true, goal ->
+ let proof =
+ match goal with
+ | Some goal ->
+ let _, proof, _, _, _ = goal in Some proof
+ | None -> None
+ in
+ ParamodulationSuccess (proof (* goal *), env)
+ )
+ with SearchSpaceOver ->
+ ParamodulationFailure
;;
-let rec given_clause_fullred env passive active =
+let rec given_clause_fullred env goals theorems passive active =
let time1 = Unix.gettimeofday () in
let selection_estimate = get_selection_estimate () in
passive
else if !elapsed_time > !time_limit then (
debug_print (lazy (Printf.sprintf "Time limit (%.2f) reached: %.2f\n"
- !time_limit !elapsed_time));
+ !time_limit !elapsed_time));
make_passive [] []
) else if kept > selection_estimate then (
- debug_print (lazy (Printf.sprintf ("Too many passive equalities: pruning..." ^^
- "(kept: %d, selection_estimate: %d)\n")
- kept selection_estimate));
+ debug_print
+ (lazy (Printf.sprintf ("Too many passive equalities: pruning..." ^^
+ "(kept: %d, selection_estimate: %d)\n")
+ kept selection_estimate));
prune_passive selection_estimate active passive
) else
passive
kept_clauses := (size_of_passive passive) + (size_of_active active);
- match passive_is_empty passive with
- | true -> ParamodulationFailure
- | false ->
- let (sign, current), passive = select env passive active in
- let time1 = Unix.gettimeofday () in
- let res = forward_simplify env (sign, current) ~passive active in
- let time2 = Unix.gettimeofday () in
- forward_simpl_time := !forward_simpl_time +. (time2 -. time1);
- match res with
- | None ->
- given_clause_fullred env passive active
- | Some (sign, current) ->
- if (sign = Negative) && (is_identity env current) then (
- debug_print (lazy (Printf.sprintf "OK!!! %s %s" (string_of_sign sign)
- (string_of_equality ~env current)));
- ParamodulationSuccess (Some current, env)
- ) else (
- debug_print (lazy "\n================================================");
- debug_print (lazy (Printf.sprintf "selected: %s %s"
- (string_of_sign sign)
+(* let refl_equal = *)
+(* CicUtil.term_of_uri *)
+(* (UriManager.uri_of_string "cic:/Coq/Init/Logic/eq.ind#xpointer(1/1/1)") *)
+(* in *)
+ let goals = simplify_goals env goals ~passive active in
+ let theorems = simplify_theorems env theorems ~passive active in
+ let is_passive_empty = passive_is_empty passive in
+ try
+ let ok, goals = apply_to_goals env is_passive_empty theorems active goals in
+ if ok then
+ let proof =
+ match goals with
+ | (_, [proof, _, _])::_ -> Some proof
+ | _ -> assert false
+ in
+ ParamodulationSuccess (proof, env)
+ else
+ let _ =
+ debug_print
+ (lazy ("new_goals: " ^ (string_of_int (List.length goals))));
+ debug_print
+ (lazy
+ (String.concat "\n"
+ (List.map
+ (fun (d, gl) ->
+ let gl' =
+ List.map
+ (fun (p, _, t) ->
+ (string_of_proof p) ^ ", " ^ (CicPp.ppterm t)) gl
+ in
+ Printf.sprintf "%d: %s" d (String.concat "; " gl'))
+ goals)));
+ in
+ match is_passive_empty (* passive_is_empty passive *) with
+ | true -> (* ParamodulationFailure *)
+ given_clause_fullred env goals theorems passive active
+ | false ->
+ let (sign, current), passive = select env goals passive active in
+ let time1 = Unix.gettimeofday () in
+ let res = forward_simplify env (sign, current) ~passive active in
+ let time2 = Unix.gettimeofday () in
+ forward_simpl_time := !forward_simpl_time +. (time2 -. time1);
+ match res with
+ | None ->
+ given_clause_fullred env goals theorems passive active
+ | Some (sign, current) ->
+ if (sign = Negative) && (is_identity env current) then (
+ debug_print
+ (lazy (Printf.sprintf "OK!!! %s %s" (string_of_sign sign)
(string_of_equality ~env current)));
+ let _, proof, _, _, _ = current in
+ ParamodulationSuccess (Some proof (* current *), env)
+ ) else (
+ debug_print
+ (lazy "\n================================================");
+ debug_print (lazy (Printf.sprintf "selected: %s %s"
+ (string_of_sign sign)
+ (string_of_equality ~env current)));
+
+ let t1 = Unix.gettimeofday () in
+ let new' = infer env sign current active in
+ let t2 = Unix.gettimeofday () in
+ infer_time := !infer_time +. (t2 -. t1);
+
+ let active =
+ if is_identity env current then active
+ else
+ let al, tbl = active in
+ match sign with
+ | Negative -> (sign, current)::al, tbl
+ | Positive ->
+ al @ [(sign, current)], Indexing.index tbl current
+ in
+ let rec simplify new' active passive =
+ let t1 = Unix.gettimeofday () in
+ let new' = forward_simplify_new env new' ~passive active in
+ let t2 = Unix.gettimeofday () in
+ forward_simpl_new_time :=
+ !forward_simpl_new_time +. (t2 -. t1);
+ let t1 = Unix.gettimeofday () in
+ let active, passive, newa, retained =
+ backward_simplify env new' ~passive active in
+ let t2 = Unix.gettimeofday () in
+ backward_simpl_time := !backward_simpl_time +. (t2 -. t1);
+ 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 t1 = Unix.gettimeofday () in
- let new' = infer env sign current active in
- let t2 = Unix.gettimeofday () in
- infer_time := !infer_time +. (t2 -. t1);
-
- let active =
- if is_identity env current then active
- else
- let al, tbl = active in
- match sign with
- | Negative -> (sign, current)::al, tbl
- | Positive -> al @ [(sign, current)], Indexing.index tbl current
- in
- let rec simplify new' active passive =
- let t1 = Unix.gettimeofday () in
- let new' = forward_simplify_new env new' ~passive active in
- let t2 = Unix.gettimeofday () in
- forward_simpl_new_time := !forward_simpl_new_time +. (t2 -. t1);
- let t1 = Unix.gettimeofday () in
- let active, passive, newa, retained =
- backward_simplify env new' ~passive active in
- let t2 = Unix.gettimeofday () in
- backward_simpl_time := !backward_simpl_time +. (t2 -. t1);
- 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 k = size_of_passive passive in
- if k < (kept - 1) then
- processed_clauses := !processed_clauses + (kept - 1 - k);
-
- let _ =
- debug_print (lazy (
- Printf.sprintf "active:\n%s\n"
- (String.concat "\n"
- ((List.map
- (fun (s, e) -> (string_of_sign s) ^ " " ^
- (string_of_equality ~env e)) (fst active))))))
- in
- let _ =
- match new' with
- | neg, pos ->
- debug_print (lazy (
- Printf.sprintf "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)))))
- in
- match contains_empty env new' with
- | false, _ ->
- let passive = add_to_passive passive new' in
+ let k = size_of_passive passive in
+ if k < (kept - 1) then
+ processed_clauses := !processed_clauses + (kept - 1 - k);
+
+ let _ =
+ debug_print
+ (lazy
+ (Printf.sprintf "active:\n%s\n"
+ (String.concat "\n"
+ ((List.map
+ (fun (s, e) -> (string_of_sign s) ^ " " ^
+ (string_of_equality ~env e))
+ (fst active))))))
+ in
+ let _ =
+ match new' with
+ | neg, pos ->
+ debug_print
+ (lazy
+ (Printf.sprintf "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)))))
+ in
+ match contains_empty env new' with
+ | false, _ ->
+ let passive = add_to_passive passive new' in
(* let (_, ns), (_, ps), _ = passive in *)
(* Printf.printf "passive:\n%s\n" *)
(* (String.concat "\n" *)
(* (string_of_equality ~env e)) *)
(* (EqualitySet.elements ps)))); *)
(* print_newline (); *)
- given_clause_fullred env passive active
- | true, goal ->
- ParamodulationSuccess (goal, env)
- )
+ given_clause_fullred env goals theorems passive active
+ | true, goal ->
+ let proof =
+ match goal with
+ | Some goal -> let _, proof, _, _, _ = goal in Some proof
+ | None -> None
+ in
+ ParamodulationSuccess (proof (* goal *), env)
+ )
+ with SearchSpaceOver ->
+ ParamodulationFailure
;;
-let given_clause_ref = ref given_clause;;
-
+(* let given_clause_ref = ref given_clause;; *)
let main dbd term metasenv ugraph =
let module C = Cic in
let goal' = List.nth goals 0 in
let _, metasenv, meta_proof, _ = proof in
let _, context, goal = CicUtil.lookup_meta goal' metasenv in
- let equalities, maxm = find_equalities context proof in
- let library_equalities, maxm =
- find_library_equalities ~dbd context (proof, goal') (maxm+2)
+ let eq_indexes, equalities, maxm = find_equalities context proof in
+ let lib_eq_uris, library_equalities, maxm =
+ find_library_equalities dbd context (proof, goal') (maxm+2)
in
maxmeta := maxm+2; (* TODO ugly!! *)
let irl = CicMkImplicit.identity_relocation_list_for_metavariable context in
in
(* let new_meta_goal = Cic.Meta (goal', irl) in *)
let env = (metasenv, context, ugraph) in
+ let theorems = find_library_theorems dbd env (proof, goal') lib_eq_uris in
+ let context_hyp = find_context_hypotheses env eq_indexes in
+ let theorems = context_hyp @ theorems in
+ let _ =
+ debug_print
+ (lazy
+ (Printf.sprintf
+ "Theorems:\n-------------------------------------\n%s\n"
+ (String.concat "\n"
+ (List.map
+ (fun (t, ty, _) ->
+ Printf.sprintf
+ "Term: %s, type: %s" (CicPp.ppterm t) (CicPp.ppterm ty))
+ theorems))))
+ in
try
- let term_equality = equality_of_term new_meta_goal goal in
- let _, meta_proof, (eq_ty, left, right, ordering), _, _ = term_equality in
- if is_identity env term_equality then
- let proof =
- Cic.Appl [Cic.MutConstruct (* reflexivity *)
- (HelmLibraryObjects.Logic.eq_URI, 0, 1, []);
- eq_ty; left]
- in
- let _ =
- Printf.printf "OK, found a proof!\n";
- let names = names_of_context context in
- print_endline (PP.pp proof names)
- in
- ()
- else
+ let goal = Inference.BasicProof new_meta_goal, [], goal in
+(* let term_equality = equality_of_term new_meta_goal goal in *)
+(* let _, meta_proof, (eq_ty, left, right, ordering), _, _ = term_equality in *)
+(* if is_identity env term_equality then *)
+(* let proof = *)
+(* Cic.Appl [Cic.MutConstruct (\* reflexivity *\) *)
+(* (HelmLibraryObjects.Logic.eq_URI, 0, 1, []); *)
+(* eq_ty; left] *)
+(* in *)
+(* let _ = *)
+(* Printf.printf "OK, found a proof!\n"; *)
+(* let names = names_of_context context in *)
+(* print_endline (PP.pp proof names) *)
+(* in *)
+(* () *)
+(* else *)
let equalities =
let equalities = equalities @ library_equalities in
- debug_print (lazy (
- Printf.sprintf "equalities:\n%s\n"
- (String.concat "\n"
- (List.map string_of_equality equalities))));
+ debug_print
+ (lazy
+ (Printf.sprintf "equalities:\n%s\n"
+ (String.concat "\n"
+ (List.map string_of_equality equalities))));
debug_print (lazy "SIMPLYFYING EQUALITIES...");
let rec simpl e others others_simpl =
let active = others @ others_simpl in
let res =
List.rev (List.map snd (simpl (Positive, hd) others []))
in
- debug_print (lazy (
- Printf.sprintf "equalities AFTER:\n%s\n"
- (String.concat "\n"
- (List.map string_of_equality res))));
+ debug_print
+ (lazy
+ (Printf.sprintf "equalities AFTER:\n%s\n"
+ (String.concat "\n"
+ (List.map string_of_equality res))));
res
in
let active = make_active () in
- let passive = make_passive [term_equality] equalities in
+ let passive = make_passive [] (* [term_equality] *) equalities in
Printf.printf "\ncurrent goal: %s\n"
- (string_of_equality ~env term_equality);
+ (let _, _, g = goal in CicPp.ppterm g);
+(* (string_of_equality ~env term_equality); *)
Printf.printf "\ncontext:\n%s\n" (PP.ppcontext context);
Printf.printf "\nmetasenv:\n%s\n" (print_metasenv metasenv);
Printf.printf "\nequalities:\n%s\n"
start_time := Unix.gettimeofday ();
let res =
(if !use_fullred then given_clause_fullred else given_clause)
- env passive active
+ env [0, [goal]] theorems passive active
in
let finish = Unix.gettimeofday () in
let _ =
match res with
| ParamodulationFailure ->
Printf.printf "NO proof found! :-(\n\n"
- | ParamodulationSuccess (Some goal, env) ->
- let proof = Inference.build_proof_term goal in
-(* let proof = *)
-(* (\* let p = CicSubstitution.lift 1 proof in *\) *)
-(* let rec repl i = function *)
-(* | C.Meta _ -> C.Rel i *)
-(* | C.Appl l -> C.Appl (List.map (repl i) l) *)
-(* | C.Prod (n, s, t) -> C.Prod (n, s, repl (i+1) t) *)
-(* | C.Lambda (n, s, t) -> C.Lambda (n, s, repl (i+1) t) *)
-(* | t -> t *)
-(* in *)
-(* let p = repl 1 proof in *)
-(* p *)
-(* (\* C.Lambda (C.Anonymous, C.Rel 9, p) *\) *)
-(* in *)
+ | ParamodulationSuccess (Some proof (* goal *), env) ->
+(* let proof = Inference.build_proof_term goal in *)
+ let proof = Inference.build_proof_term proof in
+ Printf.printf "OK, found a proof!\n";
+ (* REMEMBER: we have to instantiate meta_proof, we should use
+ apply the "apply" tactic to proof and status
+ *)
+ let names = names_of_context context in
+ print_endline (PP.pp proof names);
let newmetasenv =
List.fold_left
(fun m (_, _, _, menv, _) -> m @ menv) metasenv equalities
;;
-let saturate dbd ?(full=false) ?(depth=0) ?(width=0) (proof, goal) =
+let default_depth = !maxdepth
+and default_width = !maxwidth;;
+
+let saturate
+ dbd ?(full=false) ?(depth=default_depth) ?(width=default_width) status =
let module C = Cic in
maxmeta := 0;
+ maxdepth := depth;
+ maxwidth := width;
+ let proof, goal = status in
let goal' = goal in
let uri, metasenv, meta_proof, term_to_prove = proof in
let _, context, goal = CicUtil.lookup_meta goal' metasenv in
- let equalities, maxm = find_equalities context proof in
+ let eq_indexes, equalities, maxm = find_equalities context proof in
let new_meta_goal, metasenv, type_of_goal =
let irl =
CicMkImplicit.identity_relocation_list_for_metavariable context in
let _, context, ty = CicUtil.lookup_meta goal' metasenv in
- debug_print (lazy (Printf.sprintf "\n\nTIPO DEL GOAL: %s\n" (CicPp.ppterm ty)));
+ debug_print
+ (lazy (Printf.sprintf "\n\nTIPO DEL GOAL: %s\n" (CicPp.ppterm ty)));
Cic.Meta (maxm+1, irl),
(maxm+1, context, ty)::metasenv,
ty
in
let ugraph = CicUniv.empty_ugraph in
let env = (metasenv, context, ugraph) in
-(* try *)
- let term_equality = equality_of_term new_meta_goal goal in
+ let goal = Inference.BasicProof new_meta_goal, [], goal in
let res, time =
- if is_identity env term_equality then
- let w, _, (eq_ty, left, right, o), m, a = term_equality in
- let proof =
- Cic.Appl [Cic.MutConstruct (* reflexivity *)
- (HelmLibraryObjects.Logic.eq_URI, 0, 1, []);
- eq_ty; left]
- in
- (ParamodulationSuccess
- (Some (0, Inference.BasicProof proof,
- (eq_ty, left, right, o), m, a), env), 0.)
- else
- let library_equalities, maxm =
- find_library_equalities ~dbd context (proof, goal') (maxm+2)
+ let lib_eq_uris, library_equalities, maxm =
+ find_library_equalities dbd context (proof, goal') (maxm+2)
+ in
+ maxmeta := maxm+2;
+ let equalities =
+ let equalities = equalities @ library_equalities in
+ debug_print
+ (lazy
+ (Printf.sprintf "equalities:\n%s\n"
+ (String.concat "\n"
+ (List.map string_of_equality equalities))));
+ debug_print (lazy "SIMPLYFYING EQUALITIES...");
+ let rec simpl e others others_simpl =
+ let active = others @ others_simpl in
+ let tbl =
+ List.fold_left
+ (fun t (_, e) -> Indexing.index t e)
+ (Indexing.empty_table ()) active
+ in
+ let res = forward_simplify env e (active, tbl) in
+ match others with
+ | hd::tl -> (
+ match res with
+ | None -> simpl hd tl others_simpl
+ | Some e -> simpl hd tl (e::others_simpl)
+ )
+ | [] -> (
+ match res with
+ | None -> others_simpl
+ | Some e -> e::others_simpl
+ )
in
- maxmeta := maxm+2;
- let equalities =
- let equalities = equalities @ library_equalities in
- debug_print (lazy (
- Printf.sprintf "equalities:\n%s\n"
- (String.concat "\n"
- (List.map string_of_equality equalities))));
- debug_print (lazy "SIMPLYFYING EQUALITIES...");
- let rec simpl e others others_simpl =
- let active = others @ others_simpl in
- let tbl =
- List.fold_left
- (fun t (_, e) -> Indexing.index t e)
- (Indexing.empty_table ()) active
+ match equalities with
+ | [] -> []
+ | hd::tl ->
+ let others = List.map (fun e -> (Positive, e)) tl in
+ let res =
+ List.rev (List.map snd (simpl (Positive, hd) others []))
in
- let res = forward_simplify env e (active, tbl) in
- match others with
- | hd::tl -> (
- match res with
- | None -> simpl hd tl others_simpl
- | Some e -> simpl hd tl (e::others_simpl)
- )
- | [] -> (
- match res with
- | None -> others_simpl
- | Some e -> e::others_simpl
- )
+ debug_print
+ (lazy
+ (Printf.sprintf "equalities AFTER:\n%s\n"
+ (String.concat "\n"
+ (List.map string_of_equality res))));
+ res
+ in
+ let theorems =
+ if full then
+ let thms = find_library_theorems dbd env (proof, goal') lib_eq_uris in
+ let context_hyp = find_context_hypotheses env eq_indexes in
+ context_hyp @ thms
+ else
+ let refl_equal =
+ UriManager.uri_of_string "cic:/Coq/Init/Logic/eq.ind#xpointer(1/1/1)"
in
- match equalities with
- | [] -> []
- | hd::tl ->
- let others = List.map (fun e -> (Positive, e)) tl in
- let res =
- List.rev (List.map snd (simpl (Positive, hd) others []))
- in
- debug_print (lazy (
- Printf.sprintf "equalities AFTER:\n%s\n"
- (String.concat "\n"
- (List.map string_of_equality res))));
- res
- in
- let active = make_active () in
- let passive = make_passive [term_equality] equalities in
- let start = Unix.gettimeofday () in
- let res = given_clause_fullred env passive active in
- let finish = Unix.gettimeofday () in
- (res, finish -. start)
+ let t = CicUtil.term_of_uri refl_equal in
+ let ty, _ = CicTypeChecker.type_of_aux' [] [] t CicUniv.empty_ugraph in
+ [(t, ty, [])]
+ in
+ let _ =
+ debug_print
+ (lazy
+ (Printf.sprintf
+ "Theorems:\n-------------------------------------\n%s\n"
+ (String.concat "\n"
+ (List.map
+ (fun (t, ty, _) ->
+ Printf.sprintf
+ "Term: %s, type: %s"
+ (CicPp.ppterm t) (CicPp.ppterm ty))
+ theorems))))
+ in
+ let active = make_active () in
+ let passive = make_passive [(* term_equality *)] equalities in
+ let start = Unix.gettimeofday () in
+ let res = given_clause_fullred env [0, [goal]] theorems passive active in
+ let finish = Unix.gettimeofday () in
+ (res, finish -. start)
in
match res with
- | ParamodulationSuccess (Some goal, env) ->
+ | ParamodulationSuccess (Some proof (* goal *), env) ->
debug_print (lazy "OK, found a proof!");
- let proof = Inference.build_proof_term goal in
+(* let proof = Inference.build_proof_term goal in *)
+ let proof = Inference.build_proof_term proof in
let names = names_of_context context in
let newmetasenv =
let i1 =
match new_meta_goal with
| C.Meta (i, _) -> i | _ -> assert false
in
-(* let i2 = *)
-(* match meta_proof with *)
-(* | C.Meta (i, _) -> i *)
-(* | t -> *)
-(* Printf.printf "\nHMMM!!! meta_proof: %s\ngoal': %s" *)
-(* (CicPp.pp meta_proof names) (string_of_int goal'); *)
-(* print_newline (); *)
-(* assert false *)
-(* in *)
List.filter (fun (i, _, _) -> i <> i1 && i <> goal') metasenv
in
let newstatus =
CicTypeChecker.type_of_aux' newmetasenv context proof ugraph
in
debug_print (lazy (CicPp.pp proof [](* names *)));
- debug_print (lazy
- (Printf.sprintf
- "\nGOAL was: %s\nPROOF has type: %s\nconvertible?: %s\n"
- (CicPp.pp type_of_goal names) (CicPp.pp ty names)
- (string_of_bool
- (fst (CicReduction.are_convertible
- context type_of_goal ty ug)))));
+ debug_print
+ (lazy
+ (Printf.sprintf
+ "\nGOAL was: %s\nPROOF has type: %s\nconvertible?: %s\n"
+ (CicPp.pp type_of_goal names) (CicPp.pp ty names)
+ (string_of_bool
+ (fst (CicReduction.are_convertible
+ context type_of_goal ty ug)))));
let equality_for_replace i t1 =
match t1 with
| C.Meta (n, _) -> n = i
~what:[goal'] ~with_what:[proof]
~where:meta_proof
in
- debug_print (lazy (
- Printf.sprintf "status:\n%s\n%s\n%s\n%s\n"
- (match uri with Some uri -> UriManager.string_of_uri uri
- | None -> "")
- (print_metasenv newmetasenv)
- (CicPp.pp real_proof [](* names *))
- (CicPp.pp term_to_prove names)));
+ debug_print
+ (lazy
+ (Printf.sprintf "status:\n%s\n%s\n%s\n%s\n"
+ (match uri with Some uri -> UriManager.string_of_uri uri
+ | None -> "")
+ (print_metasenv newmetasenv)
+ (CicPp.pp real_proof [](* names *))
+ (CicPp.pp term_to_prove names)));
((uri, newmetasenv, real_proof, term_to_prove), [])
with CicTypeChecker.TypeCheckerFailure _ ->
debug_print (lazy "THE PROOF DOESN'T TYPECHECK!!!");
newstatus
| _ ->
raise (ProofEngineTypes.Fail "NO proof found")
-(* with e -> *)
-(* raise (Failure "saturation failed") *)
;;
-
(* dummy function called within matita to trigger linkage *)
let init () = ();;
AutoTactic.paramodulation_tactic := saturate;
AutoTactic.term_is_equality := Inference.term_is_equality;
);;
+