let indexing_retrieval_time = ref 0.;;
-(* let my_apply_subst subst term = *)
-(* let module C = Cic in *)
-(* let lookup lift_amount meta = *)
-(* match meta with *)
-(* | C.Meta (i, _) -> ( *)
-(* try *)
-(* let _, (_, t, _) = List.find (fun (m, _) -> m = i) subst in *)
-(* (\* CicSubstitution.lift lift_amount *\)t *)
-(* with Not_found -> meta *)
-(* ) *)
-(* | _ -> assert false *)
-(* in *)
-(* let rec apply_aux lift_amount = function *)
-(* | C.Meta (i, l) as t -> lookup lift_amount t *)
-(* | C.Appl l -> C.Appl (List.map (apply_aux lift_amount) l) *)
-(* | C.Prod (nn, s, t) -> *)
-(* C.Prod (nn, apply_aux lift_amount s, apply_aux (lift_amount+1) t) *)
-(* | C.Lambda (nn, s, t) -> *)
-(* C.Lambda (nn, apply_aux lift_amount s, apply_aux (lift_amount+1) t) *)
-(* | t -> t *)
-(* in *)
-(* apply_aux 0 term *)
-(* ;; *)
-
-
-(* let apply_subst subst term = *)
-(* Printf.printf "| apply_subst:\n| subst: %s\n| term: %s\n" *)
-(* (Utils.print_subst ~prefix:" ; " subst) (CicPp.ppterm term); *)
-(* let res = my_apply_subst subst term in *)
-(* (\* let res = CicMetaSubst.apply_subst subst term in *\) *)
-(* Printf.printf "| res: %s\n" (CicPp.ppterm res); *)
-(* print_endline "|"; *)
-(* res *)
-(* ;; *)
-
-(* let apply_subst = my_apply_subst *)
let apply_subst = CicMetaSubst.apply_subst
-(* let apply_subst = *)
-(* let profile = CicUtil.profile "apply_subst" in *)
-(* (fun s a -> profile (apply_subst s) a) *)
-(* ;; *)
-
(*
(* NO INDEXING *)
+let init_index () = ()
+
let empty_table () = []
let index table equality =
(*
(* PATH INDEXING *)
+let init_index () = ()
+
let empty_table () =
Path_indexing.PSTrie.empty
;;
;;
-(* let get_candidates = *)
-(* let profile = CicUtil.profile "Indexing.get_candidates" in *)
-(* (fun mode tree term -> profile.profile (get_candidates mode tree) term) *)
-(* ;; *)
-
-
let match_unif_time_ok = ref 0.;;
let match_unif_time_no = ref 0.;;
+(*
+ finds the first equality in the index that matches "term", of type "termty"
+ termty can be Implicit if it is not needed. The result (one of the sides of
+ the equality, actually) should be not greater (wrt the term ordering) than
+ term
+
+ Format of the return value:
+
+ (term to substitute, [Cic.Rel 1 properly lifted - see the various
+ build_newtarget functions inside the various
+ demodulation_* functions]
+ substitution used for the matching,
+ metasenv,
+ ugraph, [substitution, metasenv and ugraph have the same meaning as those
+ returned by CicUnification.fo_unif]
+ (equality where the matching term was found, [i.e. the equality to use as
+ rewrite rule]
+ uri [either eq_ind_URI or eq_ind_r_URI, depending on the direction of
+ the equality: this is used to build the proof term, again see one of
+ the build_newtarget functions]
+ ))
+*)
let rec find_matches metasenv context ugraph lift_amount term termty =
let module C = Cic in
let module U = Utils in
let module M = CicMetaSubst in
let module HL = HelmLibraryObjects in
let cmp = !Utils.compare_terms in
-(* let names = Utils.names_of_context context in *)
-(* let termty, ugraph = *)
-(* CicTypeChecker.type_of_aux' metasenv context term ugraph *)
-(* in *)
let check = match termty with C.Implicit None -> false | _ -> true in
function
| [] -> None
let pos, (_, proof, (ty, left, right, o), metas, args) = candidate in
if check && not (fst (CicReduction.are_convertible
~metasenv context termty ty ugraph)) then (
-(* debug_print (lazy ( *)
-(* Printf.sprintf "CANDIDATE HAS WRONG TYPE: %s required, %s found" *)
-(* (CicPp.pp termty names) (CicPp.pp ty names))); *)
find_matches metasenv context ugraph lift_amount term termty tl
) else
- let do_match c (* other *) eq_URI =
+ let do_match c eq_URI =
let subst', metasenv', ugraph' =
let t1 = Unix.gettimeofday () in
try
in
if o <> U.Incomparable then
try
- do_match c (* other *) eq_URI
+ do_match c eq_URI
with Inference.MatchingFailure ->
find_matches metasenv context ugraph lift_amount term termty tl
else
let res =
- try do_match c (* other *) eq_URI
+ try do_match c eq_URI
with Inference.MatchingFailure -> None
in
match res with
| Some (_, s, _, _, _) ->
- let c' = (* M. *)apply_subst s c
- and other' = (* M. *)apply_subst s other in
+ let c' = apply_subst s c
+ and other' = apply_subst s other in
let order = cmp c' other' in
let names = U.names_of_context context in
-(* let _ = *)
-(* debug_print *)
-(* (Printf.sprintf "OK matching: %s and %s, order: %s" *)
-(* (CicPp.ppterm c') *)
-(* (CicPp.ppterm other') *)
-(* (Utils.string_of_comparison order)); *)
-(* debug_print *)
-(* (Printf.sprintf "subst:\n%s\n" (Utils.print_subst s)) *)
-(* in *)
if order = U.Gt then
res
else
;;
+(*
+ as above, but finds all the matching equalities, and the matching condition
+ can be either Inference.matching or Inference.unification
+*)
let rec find_all_matches ?(unif_fun=Inference.unification)
metasenv context ugraph lift_amount term termty =
let module C = Cic in
let module M = CicMetaSubst in
let module HL = HelmLibraryObjects in
let cmp = !Utils.compare_terms in
-(* let names = Utils.names_of_context context in *)
-(* let termty, ugraph = *)
-(* CicTypeChecker.type_of_aux' metasenv context term ugraph *)
-(* in *)
-(* let _ = *)
-(* match term with *)
-(* | C.Meta _ -> assert false *)
-(* | _ -> () *)
-(* in *)
function
| [] -> []
| candidate::tl ->
let pos, (_, _, (ty, left, right, o), metas, args) = candidate in
-(* if not (fst (CicReduction.are_convertible *)
-(* ~metasenv context termty ty ugraph)) then ( *)
-(* (\* debug_print (lazy ( *\) *)
-(* (\* Printf.sprintf "CANDIDATE HAS WRONG TYPE: %s required, %s found" *\) *)
-(* (\* (CicPp.pp termty names) (CicPp.pp ty names))); *\) *)
-(* find_all_matches ~unif_fun metasenv context ugraph *)
-(* lift_amount term termty tl *)
-(* ) else *)
- let do_match c (* other *) eq_URI =
- let subst', metasenv', ugraph' =
- let t1 = Unix.gettimeofday () in
- try
- let r =
- unif_fun (metasenv @ metas) context
- term (S.lift lift_amount c) ugraph in
- let t2 = Unix.gettimeofday () in
- match_unif_time_ok := !match_unif_time_ok +. (t2 -. t1);
- r
- with
- | Inference.MatchingFailure
- | CicUnification.UnificationFailure _
- | CicUnification.Uncertain _ as e ->
- let t2 = Unix.gettimeofday () in
- match_unif_time_no := !match_unif_time_no +. (t2 -. t1);
- raise e
- in
- (C.Rel (1 + lift_amount), subst', metasenv', ugraph',
- (candidate, eq_URI))
- in
- let c, other, eq_URI =
- if pos = Utils.Left then left, right, Utils.eq_ind_URI ()
- else right, left, Utils.eq_ind_r_URI ()
- in
- if o <> U.Incomparable then
+ let do_match c eq_URI =
+ let subst', metasenv', ugraph' =
+ let t1 = Unix.gettimeofday () in
try
- let res = do_match c (* other *) eq_URI in
- res::(find_all_matches ~unif_fun metasenv context ugraph
- lift_amount term termty tl)
+ let r =
+ unif_fun (metasenv @ metas) context
+ term (S.lift lift_amount c) ugraph in
+ let t2 = Unix.gettimeofday () in
+ match_unif_time_ok := !match_unif_time_ok +. (t2 -. t1);
+ r
with
| Inference.MatchingFailure
| CicUnification.UnificationFailure _
- | CicUnification.Uncertain _ ->
+ | CicUnification.Uncertain _ as e ->
+ let t2 = Unix.gettimeofday () in
+ match_unif_time_no := !match_unif_time_no +. (t2 -. t1);
+ raise e
+ in
+ (C.Rel (1 + lift_amount), subst', metasenv', ugraph',
+ (candidate, eq_URI))
+ in
+ let c, other, eq_URI =
+ if pos = Utils.Left then left, right, Utils.eq_ind_URI ()
+ else right, left, Utils.eq_ind_r_URI ()
+ in
+ if o <> U.Incomparable then
+ try
+ let res = do_match c eq_URI in
+ res::(find_all_matches ~unif_fun metasenv context ugraph
+ lift_amount term termty tl)
+ with
+ | Inference.MatchingFailure
+ | CicUnification.UnificationFailure _
+ | CicUnification.Uncertain _ ->
+ find_all_matches ~unif_fun metasenv context ugraph
+ lift_amount term termty tl
+ else
+ try
+ let res = do_match c eq_URI in
+ match res with
+ | _, s, _, _, _ ->
+ let c' = apply_subst s c
+ and other' = apply_subst s other in
+ let order = cmp c' other' in
+ let names = U.names_of_context context in
+ if order <> U.Lt && order <> U.Le then
+ res::(find_all_matches ~unif_fun metasenv context ugraph
+ lift_amount term termty tl)
+ else
+ find_all_matches ~unif_fun metasenv context ugraph
+ lift_amount term termty tl
+ with
+ | Inference.MatchingFailure
+ | CicUnification.UnificationFailure _
+ | CicUnification.Uncertain _ ->
find_all_matches ~unif_fun metasenv context ugraph
lift_amount term termty tl
- else
- try
- let res = do_match c (* other *) eq_URI in
- match res with
- | _, s, _, _, _ ->
- let c' = (* M. *)apply_subst s c
- and other' = (* M. *)apply_subst s other in
- let order = cmp c' other' in
- let names = U.names_of_context context in
- if order <> U.Lt && order <> U.Le then
- res::(find_all_matches ~unif_fun metasenv context ugraph
- lift_amount term termty tl)
- else
- find_all_matches ~unif_fun metasenv context ugraph
- lift_amount term termty tl
- with
- | Inference.MatchingFailure
- | CicUnification.UnificationFailure _
- | CicUnification.Uncertain _ ->
- find_all_matches ~unif_fun metasenv context ugraph
- lift_amount term termty tl
;;
+(*
+ returns true if target is subsumed by some equality in table
+*)
let subsumption env table target =
- let _, (ty, left, right, _), tmetas, _ = target in
+ let _, _, (ty, left, right, _), tmetas, _ = target in
let metasenv, context, ugraph = env in
let metasenv = metasenv @ tmetas in
let samesubst subst subst' =
in
let rec ok what = function
| [] -> false, []
- | (_, subst, menv, ug, ((pos, (_, _, (_, l, r, o), _, _)), _))::tl ->
+ | (_, subst, menv, ug, ((pos, (_, _, (_, l, r, o), m, _)), _))::tl ->
try
let other = if pos = Utils.Left then r else l in
let subst', menv', ug' =
let t1 = Unix.gettimeofday () in
try
let r =
- Inference.matching metasenv context what other ugraph in
+ Inference.matching (metasenv @ menv @ m) context what other ugraph
+ in
let t2 = Unix.gettimeofday () in
match_unif_time_ok := !match_unif_time_ok +. (t2 -. t1);
r
ok what tl
in
let r, subst = ok right leftr in
- if r then
- true, subst
- else
- let rightr =
- match right with
- | Cic.Meta _ -> []
- | _ ->
- let rightc = get_candidates Matching table right in
- find_all_matches ~unif_fun:Inference.matching
- metasenv context ugraph 0 right ty rightc
- in
- ok left rightr
+ let r, s =
+ if r then
+ true, subst
+ else
+ let rightr =
+ match right with
+ | Cic.Meta _ -> []
+ | _ ->
+ let rightc = get_candidates Matching table right in
+ find_all_matches ~unif_fun:Inference.matching
+ metasenv context ugraph 0 right ty rightc
+ in
+ ok left rightr
+ in
+(* (if r then *)
+(* debug_print *)
+(* (lazy *)
+(* (Printf.sprintf "SUBSUMPTION! %s\n%s\n" *)
+(* (Inference.string_of_equality target) (Utils.print_subst s)))); *)
+ r, s
;;
let demod_counter = ref 1;;
+(** demodulation, when target is an equality *)
let rec demodulation_equality newmeta env table sign target =
let module C = Cic in
let module S = CicSubstitution in
in
let what, other = if pos = Utils.Left then what, other else other, what in
let newterm, newproof =
- let bo = (* M. *)apply_subst subst (S.subst other t) in
-(* let t' = *)
-(* let name = C.Name ("x_Demod_" ^ (string_of_int !demod_counter)) in *)
-(* incr demod_counter; *)
-(* let l, r = *)
-(* if is_left then t, S.lift 1 right else S.lift 1 left, t in *)
-(* (name, ty, S.lift 1 eq_ty, l, r) *)
-(* in *)
+ let bo = apply_subst subst (S.subst other t) in
let name = C.Name ("x_Demod_" ^ (string_of_int !demod_counter)) in
incr demod_counter;
let bo' =
incr maxmeta;
let irl =
CicMkImplicit.identity_relocation_list_for_metavariable context in
- Printf.printf "\nADDING META: %d\n" !maxmeta;
- print_newline ();
+(* debug_print (lazy (Printf.sprintf "\nADDING META: %d\n" !maxmeta)); *)
+(* print_newline (); *)
C.Meta (!maxmeta, irl)
in
-(* let target' = *)
let eq_found =
let proof' =
-(* let ens = *)
-(* if pos = Utils.Left then *)
-(* build_ens_for_sym_eq ty what other *)
-(* else *)
-(* build_ens_for_sym_eq ty other what *)
let termlist =
if pos = Utils.Left then [ty; what; other]
else [ty; other; what]
in
let target_proof =
let pb =
- Inference.ProofBlock (subst, eq_URI, (name, ty), bo'(* t' *),
+ Inference.ProofBlock (subst, eq_URI, (name, ty), bo',
eq_found, Inference.BasicProof metaproof)
in
match proof with
| Inference.BasicProof _ ->
print_endline "replacing a BasicProof";
pb
- | Inference.ProofGoalBlock (_, parent_proof(* parent_eq *)) ->
+ | Inference.ProofGoalBlock (_, parent_proof) ->
print_endline "replacing another ProofGoalBlock";
- Inference.ProofGoalBlock (pb, parent_proof(* parent_eq *))
+ Inference.ProofGoalBlock (pb, parent_proof)
| _ -> assert false
in
-(* (0, target_proof, (eq_ty, left, right, order), metas, args) *)
-(* in *)
let refl =
C.Appl [C.MutConstruct (* reflexivity *)
(LibraryObjects.eq_URI (), 0, 1, []);
eq_ty; if is_left then right else left]
in
(bo,
- Inference.ProofGoalBlock (Inference.BasicProof refl, target_proof(* target' *)))
+ Inference.ProofGoalBlock (Inference.BasicProof refl, target_proof))
in
let left, right = if is_left then newterm, right else left, newterm in
let m = (Inference.metas_of_term left) @ (Inference.metas_of_term right) in
let newmetasenv = List.filter (fun (i, _, _) -> List.mem i m) metas
and newargs = args
-(* let a = *)
-(* List.filter *)
-(* (function C.Meta (i, _) -> List.mem i m | _ -> assert false) args in *)
-(* let delta = (List.length args) - (List.length a) in *)
-(* if delta > 0 then *)
-(* let first = List.hd a in *)
-(* let rec aux l = function *)
-(* | 0 -> l *)
-(* | d -> let l = aux l (d-1) in l @ [first] *)
-(* in *)
-(* aux a delta *)
-(* else *)
-(* a *)
in
let ordering = !Utils.compare_terms left right in
!maxmeta, res
in
let res = demodulation_aux metasenv' context ugraph table 0 left in
- match res with
- | Some t ->
- let newmeta, newtarget = build_newtarget true t in
- if (Inference.is_identity (metasenv', context, ugraph) newtarget) ||
- (Inference.meta_convertibility_eq target newtarget) then
- newmeta, newtarget
- else
-(* if subsumption env table newtarget then *)
-(* newmeta, build_identity newtarget *)
-(* else *)
- demodulation_equality newmeta env table sign newtarget
- | None ->
- let res = demodulation_aux metasenv' context ugraph table 0 right in
- match res with
- | Some t ->
- let newmeta, newtarget = build_newtarget false t in
- if (Inference.is_identity (metasenv', context, ugraph) newtarget) ||
+ let newmeta, newtarget =
+ match res with
+ | Some t ->
+ let newmeta, newtarget = build_newtarget true t in
+ if (Inference.is_identity (metasenv', context, ugraph) newtarget) ||
(Inference.meta_convertibility_eq target newtarget) then
- newmeta, newtarget
- else
-(* if subsumption env table newtarget then *)
-(* newmeta, build_identity newtarget *)
-(* else *)
- demodulation_equality newmeta env table sign newtarget
- | None ->
- newmeta, target
+ newmeta, newtarget
+ else
+ demodulation_equality newmeta env table sign newtarget
+ | None ->
+ let res = demodulation_aux metasenv' context ugraph table 0 right in
+ match res with
+ | Some t ->
+ let newmeta, newtarget = build_newtarget false t in
+ if (Inference.is_identity (metasenv', context, ugraph) newtarget) ||
+ (Inference.meta_convertibility_eq target newtarget) then
+ newmeta, newtarget
+ else
+ demodulation_equality newmeta env table sign newtarget
+ | None ->
+ newmeta, target
+ in
+ (* newmeta, newtarget *)
+ (* tentiamo di ridurre usando CicReduction.normalize *)
+ let w, p, (ty, left, right, o), m, a = newtarget in
+ let left' = ProofEngineReduction.simpl context left in
+ let right' = ProofEngineReduction.simpl context right in
+ let newleft =
+ if !Utils.compare_terms left' left = Utils.Lt then left' else left in
+ let newright =
+ if !Utils.compare_terms right' right = Utils.Lt then right' else right in
+(* if newleft != left || newright != right then ( *)
+(* debug_print *)
+(* (lazy *)
+(* (Printf.sprintf "left: %s, left': %s\nright: %s, right': %s\n" *)
+(* (CicPp.ppterm left) (CicPp.ppterm left') (CicPp.ppterm right) *)
+(* (CicPp.ppterm right'))) *)
+(* ); *)
+ let w' = Utils.compute_equality_weight ty newleft newright in
+ let o' = !Utils.compare_terms newleft newright in
+ newmeta, (w', p, (ty, newleft, newright, o'), m, a)
;;
+(**
+ Performs the beta expansion of the term "term" w.r.t. "table",
+ i.e. returns the list of all the terms t s.t. "(t term) = t2", for some t2
+ in table.
+*)
let rec betaexpand_term metasenv context ugraph table lift_amount term =
let module C = Cic in
let module S = CicSubstitution in
let sup_l_counter = ref 1;;
+(**
+ superposition_left
+ returns a list of new clauses inferred with a left superposition step
+ the negative equation "target" and one of the positive equations in "table"
+*)
let superposition_left newmeta (metasenv, context, ugraph) table target =
let module C = Cic in
let module S = CicSubstitution in
let maxmeta = ref newmeta in
let build_new (bo, s, m, ug, (eq_found, eq_URI)) =
- print_endline "\nSUPERPOSITION LEFT\n";
-
+(* debug_print (lazy "\nSUPERPOSITION LEFT\n"); *)
+
let time1 = Unix.gettimeofday () in
let pos, (_, proof', (ty, what, other, _), menv', args') = eq_found in
let what, other = if pos = Utils.Left then what, other else other, what in
let newgoal, newproof =
- let bo' = (* M. *)apply_subst s (S.subst other bo) in
-(* let t' = *)
-(* let name = C.Name ("x_SupL_" ^ (string_of_int !sup_l_counter)) in *)
-(* incr sup_l_counter; *)
-(* let l, r = *)
-(* if ordering = U.Gt then bo, S.lift 1 right else S.lift 1 left, bo in *)
-(* (name, ty, S.lift 1 eq_ty, l, r) *)
-(* in *)
+ let bo' = apply_subst s (S.subst other bo) in
let name = C.Name ("x_SupL_" ^ (string_of_int !sup_l_counter)) in
incr sup_l_counter;
let bo'' =
CicMkImplicit.identity_relocation_list_for_metavariable context in
C.Meta (!maxmeta, irl)
in
-(* let target' = *)
- let eq_found =
- let proof' =
-(* let ens = *)
-(* if pos = Utils.Left then *)
-(* build_ens_for_sym_eq ty what other *)
-(* else *)
-(* build_ens_for_sym_eq ty other what *)
-(* in *)
- let termlist =
- if pos = Utils.Left then [ty; what; other]
- else [ty; other; what]
- in
- Inference.ProofSymBlock (termlist, proof')
- in
- let what, other =
- if pos = Utils.Left then what, other else other, what
+ let eq_found =
+ let proof' =
+ let termlist =
+ if pos = Utils.Left then [ty; what; other]
+ else [ty; other; what]
in
- pos, (0, proof', (ty, other, what, Utils.Incomparable), menv', args')
+ Inference.ProofSymBlock (termlist, proof')
in
- let target_proof =
- let pb =
- Inference.ProofBlock (s, eq_URI, (name, ty), bo''(* t' *), eq_found,
- Inference.BasicProof metaproof)
- in
- match proof with
- | Inference.BasicProof _ ->
- print_endline "replacing a BasicProof";
- pb
- | Inference.ProofGoalBlock (_, parent_proof(* parent_eq *)) ->
- print_endline "replacing another ProofGoalBlock";
- Inference.ProofGoalBlock (pb, parent_proof(* parent_eq *))
- | _ -> assert false
+ let what, other =
+ if pos = Utils.Left then what, other else other, what
+ in
+ pos, (0, proof', (ty, other, what, Utils.Incomparable), menv', args')
+ in
+ let target_proof =
+ let pb =
+ Inference.ProofBlock (s, eq_URI, (name, ty), bo'', eq_found,
+ Inference.BasicProof metaproof)
in
-(* (weight, target_proof, (eq_ty, left, right, ordering), [], []) *)
-(* in *)
+ match proof with
+ | Inference.BasicProof _ ->
+(* debug_print (lazy "replacing a BasicProof"); *)
+ pb
+ | Inference.ProofGoalBlock (_, parent_proof) ->
+(* debug_print (lazy "replacing another ProofGoalBlock"); *)
+ Inference.ProofGoalBlock (pb, parent_proof)
+ | _ -> assert false
+ in
let refl =
C.Appl [C.MutConstruct (* reflexivity *)
(LibraryObjects.eq_URI (), 0, 1, []);
eq_ty; if ordering = U.Gt then right else left]
in
(bo',
- Inference.ProofGoalBlock (Inference.BasicProof refl, target_proof(* target' *)))
+ Inference.ProofGoalBlock (Inference.BasicProof refl, target_proof))
in
let left, right =
if ordering = U.Gt then newgoal, right else left, newgoal in
let sup_r_counter = ref 1;;
+(**
+ superposition_right
+ returns a list of new clauses inferred with a right superposition step
+ between the positive equation "target" and one in the "table" "newmeta" is
+ the first free meta index, i.e. the first number above the highest meta
+ index: its updated value is also returned
+*)
let superposition_right newmeta (metasenv, context, ugraph) table target =
let module C = Cic in
let module S = CicSubstitution in
let res l r =
List.filter
(fun (_, subst, _, _, _) ->
- let subst = (* M. *)apply_subst subst in
+ let subst = apply_subst subst in
let o = !Utils.compare_terms (subst l) (subst r) in
o <> U.Lt && o <> U.Le)
(fst (betaexpand_term metasenv' context ugraph table 0 l))
let pos, (_, proof', (ty, what, other, _), menv', args') = eq_found in
let what, other = if pos = Utils.Left then what, other else other, what in
let newgoal, newproof =
- let bo' = (* M. *)apply_subst s (S.subst other bo) in
+ let bo' = apply_subst s (S.subst other bo) in
let t' =
let name = C.Name ("x_SupR_" ^ (string_of_int !sup_r_counter)) in
incr sup_r_counter;
S.lift 1 eq_ty; l; r]
in
bo',
- Inference.ProofBlock (
- s, eq_URI, (name, ty), bo''(* t' *), eq_found, eqproof)
+ Inference.ProofBlock (s, eq_URI, (name, ty), bo'', eq_found, eqproof)
in
let newmeta, newequality =
let left, right =
- if ordering = U.Gt then newgoal, (* M. *)apply_subst s right
- else (* M. *)apply_subst s left, newgoal in
+ if ordering = U.Gt then newgoal, apply_subst s right
+ else apply_subst s left, newgoal in
let neworder = !Utils.compare_terms left right
and newmenv = newmetas @ menv'
and newargs = args @ args' in
-(* let m = *)
-(* (Inference.metas_of_term left) @ (Inference.metas_of_term right) in *)
-(* let a = *)
-(* List.filter *)
-(* (function C.Meta (i, _) -> List.mem i m | _ -> assert false) *)
-(* (args @ args') *)
-(* in *)
-(* let delta = (List.length args) - (List.length a) in *)
-(* if delta > 0 then *)
-(* let first = List.hd a in *)
-(* let rec aux l = function *)
-(* | 0 -> l *)
-(* | d -> let l = aux l (d-1) in l @ [first] *)
-(* in *)
-(* aux a delta *)
-(* else *)
-(* a *)
-(* in *)
let eq' =
let w = Utils.compute_equality_weight eq_ty left right in
(w, newproof, (eq_ty, left, right, neworder), newmenv, newargs)
in
let new1 = List.map (build_new U.Gt) res1
and new2 = List.map (build_new U.Lt) res2 in
-(* let ok = function *)
-(* | _, _, (_, left, right, _), _, _ -> *)
-(* not (fst (CR.are_convertible context left right ugraph)) *)
-(* in *)
let ok e = not (Inference.is_identity (metasenv, context, ugraph) e) in
(!maxmeta,
(List.filter ok (new1 @ new2)))
;;
+(** demodulation, when the target is a goal *)
let rec demodulation_goal newmeta env table goal =
let module C = Cic in
let module S = CicSubstitution in
with CicUtil.Meta_not_found _ -> ty
in
let newterm, newproof =
- let bo = (* M. *)apply_subst subst (S.subst other t) in
+ let bo = apply_subst subst (S.subst other t) in
let bo' = apply_subst subst t in
let name = C.Name ("x_DemodGoal_" ^ (string_of_int !demod_counter)) in
incr demod_counter;
incr maxmeta;
let irl =
CicMkImplicit.identity_relocation_list_for_metavariable context in
- Printf.printf "\nADDING META: %d\n" !maxmeta;
- print_newline ();
+(* debug_print (lazy (Printf.sprintf "\nADDING META: %d\n" !maxmeta)); *)
C.Meta (!maxmeta, irl)
in
let eq_found =
let proof' =
-(* let ens = *)
-(* if pos = Utils.Left then build_ens_for_sym_eq ty what other *)
-(* else build_ens_for_sym_eq ty other what *)
-(* in *)
let termlist =
if pos = Utils.Left then [ty; what; other]
else [ty; other; what]
in
let rec repl = function
| Inference.NoProof ->
- debug_print (lazy "replacing a NoProof");
+(* debug_print (lazy "replacing a NoProof"); *)
pb
| Inference.BasicProof _ ->
- debug_print (lazy "replacing a BasicProof");
+(* debug_print (lazy "replacing a BasicProof"); *)
pb
| Inference.ProofGoalBlock (_, parent_proof) ->
- debug_print (lazy "replacing another ProofGoalBlock");
+(* debug_print (lazy "replacing another ProofGoalBlock"); *)
Inference.ProofGoalBlock (pb, parent_proof)
| (Inference.SubProof (term, meta_index, p) as subproof) ->
- debug_print
- (lazy
- (Printf.sprintf "replacing %s"
- (Inference.string_of_proof subproof)));
+(* debug_print *)
+(* (lazy *)
+(* (Printf.sprintf "replacing %s" *)
+(* (Inference.string_of_proof subproof))); *)
Inference.SubProof (term, meta_index, repl p)
| _ -> assert false
in repl proof
;;
+(** demodulation, when the target is a theorem *)
let rec demodulation_theorem newmeta env table theorem =
let module C = Cic in
let module S = CicSubstitution in