let default_sig = function
| Eq ->
- let uri = NUri.uri_of_string "cic:/matita/ng/Plogic/equality/eq.ind" in
+ let uri = NUri.uri_of_string "cic:/matita/basics/logic/eq.ind" in
let ref = NReference.reference_of_spec uri (NReference.Ind(true,0,2)) in
NCic.Const ref
| EqInd_l ->
- let uri = NUri.uri_of_string "cic:/matita/ng/Plogic/equality/rewrite_l.con" in
+ let uri = NUri.uri_of_string "cic:/matita/basics/logic/rewrite_l.con" in
let ref = NReference.reference_of_spec uri (NReference.Def(1)) in
NCic.Const ref
| EqInd_r ->
- let uri = NUri.uri_of_string "cic:/matita/ng/Plogic/equality/rewrite_r.con" in
+ let uri = NUri.uri_of_string "cic:/matita/basics/logic/rewrite_r.con" in
let ref = NReference.reference_of_spec uri (NReference.Def(3)) in
NCic.Const ref
| Refl ->
- let uri = NUri.uri_of_string "cic:/matita/ng/Plogic/equality/eq.ind" in
+ let uri = NUri.uri_of_string "cic:/matita/basics/logic/eq.ind" in
let ref = NReference.reference_of_spec uri (NReference.Con(0,1,2)) in
NCic.Const ref
let eq_refl() = debug (!eqsig Refl) "refl";;
- let extract lift vl t =
+ let extract status lift vl t =
let rec pos i = function
| [] -> raise Not_found
| j :: tl when j <> i -> 1+ pos i tl
in
let vl_len = List.length vl in
let rec extract = function
- | Terms.Leaf x -> NCicSubstitution.lift (vl_len+lift) x
+ | Terms.Leaf x -> NCicSubstitution.lift status (vl_len+lift) x
| Terms.Var j ->
(try NCic.Rel (pos j vl) with Not_found -> NCic.Implicit `Term)
| Terms.Node l -> NCic.Appl (List.map extract l)
;;
- let mk_predicate hole_type amount ft p1 vl =
+ let mk_predicate status hole_type amount ft p1 vl =
let rec aux t p =
match p with
| [] -> NCic.Rel 1
HExtlib.list_mapi
(fun t i ->
if i = n then aux t tl
- else extract amount (0::vl) t)
+ else extract status amount (0::vl) t)
l
in
NCic.Appl l
| _ -> assert false
- let mk_morphism eq amount ft pl vl =
+ let mk_morphism status eq amount ft pl vl =
let rec aux t p =
match p with
| [] -> eq
List.fold_left
(fun (i,acc) t ->
i+1,
- let f = extract amount vl f in
+ let f = extract status amount vl f in
if i = n then
let imp = NCic.Implicit `Term in
NCic.Appl (dag::imp::imp::imp(* f *)::imp::imp::
[aux t tl])
else
- NCicUntrusted.mk_appl acc [extract amount vl t]
- ) (1,extract amount vl f) l)
+ NCicUntrusted.mk_appl acc [extract status amount vl t]
+ ) (1,extract status amount vl f) l)
in aux ft (List.rev pl)
;;
- let mk_proof ?(demod=false) (bag : NCic.term Terms.bag) mp subst steps =
+ let mk_proof status ?(demod=false) (bag : NCic.term Terms.bag) mp subst steps=
let module NCicBlob =
NCicBlob.NCicBlob(
struct
let proof_type =
let lit,_,_ = get_literal mp in
let lit = Subst.apply_subst subst lit in
- extract 0 [] lit in
+ extract status 0 [] lit in
(* composition of all subst acting on goal *)
let res_subst =
let rec rsaux ongoal acc =
let lit,vl,proof = get_literal id in
if not ongoal && id = mp then
let lit = Subst.apply_subst subst lit in
- let eq_ty = extract amount [] lit in
+ let eq_ty = extract status amount [] lit in
let refl =
if demod then NCic.Implicit `Term
else mk_refl eq_ty in
(* prerr_endline ("Reached m point, id=" ^ (string_of_int id));
(NCic.LetIn ("clause_" ^ string_of_int id, eq_ty, refl,
aux true ((id,([],lit))::seen) (id::tl))) *)
- NCicSubstitution.subst
+ NCicSubstitution.subst status
~avoid_beta_redexes:true ~no_implicit:false refl
(aux true ((id,([],lit))::seen) (id::tl))
else
(*
prerr_endline ("Exact for " ^ (string_of_int id));
NCic.LetIn ("clause_" ^ string_of_int id,
- close_with_forall vl (extract amount vl lit),
- close_with_lambdas vl (extract amount vl ft),
+ close_with_forall vl (extract status amount vl lit),
+ close_with_lambdas vl (extract status amount vl ft),
aux ongoal
((id,(List.map (fun x -> Terms.Var x) vl,lit))::seen) tl)
*)
- NCicSubstitution.subst
+ NCicSubstitution.subst status
~avoid_beta_redexes:true ~no_implicit:false
- (close_with_lambdas vl (extract amount vl ft))
+ (close_with_lambdas vl (extract status amount vl ft))
(aux ongoal
((id,(List.map (fun x -> Terms.Var x) vl,lit))::seen) tl)
| Terms.Step (_, id1, id2, dir, pos, subst) ->
let proof_of_id id =
let vars = List.rev (vars_of id seen) in
let args = List.map (Subst.apply_subst subst) vars in
- let args = List.map (extract amount vl) args in
+ let args = List.map (extract status amount vl) args in
let rel_for_id = NCic.Rel (List.length vl + position id seen) in
if args = [] then rel_for_id
else NCic.Appl (rel_for_id::args)
let id2_ty,l,r =
match ty_of id2 seen with
| Terms.Node [ _; t; l; r ] ->
- extract amount vl (Subst.apply_subst subst t),
- extract amount vl (Subst.apply_subst subst l),
- extract amount vl (Subst.apply_subst subst r)
+ extract status amount vl (Subst.apply_subst subst t),
+ extract status amount vl (Subst.apply_subst subst l),
+ extract status amount vl (Subst.apply_subst subst r)
| _ -> assert false
in
(*prerr_endline "mk_predicate :";
let id2_ty,l,r =
match ty_of id2 seen with
| Terms.Node [ _; t; l; r ] ->
- extract amount vl (Subst.apply_subst subst t),
- extract amount vl (Subst.apply_subst subst l),
- extract amount vl (Subst.apply_subst subst r)
+ extract status amount vl (Subst.apply_subst subst t),
+ extract status amount vl (Subst.apply_subst subst l),
+ extract status amount vl (Subst.apply_subst subst r)
| _ -> assert false
in
(*
prerr_endline ("Positions :" ^
(String.concat ", "
(List.map string_of_int pos)));*)
- mk_predicate
+ mk_predicate status
id2_ty amount (Subst.apply_subst subst id1_ty) pos vl,
id2_ty,
l,r
let body = aux ongoal
((id,(List.map (fun x -> Terms.Var x) vl,lit))::seen) tl
in
- let occ= NCicUntrusted.count_occurrences [] 1 body in
+ let occ =
+ NCicUntrusted.count_occurrences status [] 1 body in
if occ <= 1 then
- NCicSubstitution.subst
+ NCicSubstitution.subst status
~avoid_beta_redexes:true ~no_implicit:false
(close_with_lambdas vl rewrite_step) body
else
NCic.LetIn ("clause_" ^ string_of_int id,
- close_with_forall vl (extract amount vl lit),
+ close_with_forall vl (extract status amount vl lit),
(* NCic.Implicit `Type, *)
close_with_lambdas vl rewrite_step, body)
in