-(* cOpyright (C) 2005, HELM Team.
+(* Copyright (C) 2005, HELM Team.
*
* This file is part of HELM, an Hypertextual, Electronic
* Library of Mathematics, developed at the Computer Science
and goal_proof = (rule * Utils.pos * int * Subst.substitution * Cic.term) list
;;
(* the hashtbl eq_id -> proof, max_eq_id *)
-type equality_bag = (int,equality) Hashtbl.t * int ref
+module IntOt = struct type t = int let compare = Pervasives.compare end
+module M = Map.Make(IntOt)
+type equality_bag = equality M.t * int
type goal = goal_proof * Cic.metasenv * Cic.term
(* globals *)
-let mk_equality_bag () =
- Hashtbl.create 1024, ref 0
-;;
+let mk_equality_bag () = M.empty, 10000 ;;
-let freshid (_,i) =
- incr i; !i
-;;
+let freshid (m,i) = (m,i+1), i+1 ;;
-let add_to_bag (id_to_eq,_) id eq =
- Hashtbl.add id_to_eq id eq
-;;
+let add_to_bag (id_to_eq,i) id eq = M.add id eq id_to_eq,i ;;
let uncomparable = fun _ -> 0
let mk_equality bag (weight,p,(ty,l,r,o),m) =
- let id = freshid bag in
+ let bag, id = freshid bag in
let eq = (uncomparable,weight,p,(ty,l,r,o),m,id) in
- add_to_bag bag id eq;
- eq
+ let bag = add_to_bag bag id eq in
+ bag, eq
;;
let mk_tmp_equality (weight,(ty,l,r,o),m) =
let open_equality (_,weight,proof,(ty,l,r,o),m,id) =
(weight,proof,(ty,l,r,o),m,id)
+let id_of e =
+ let _,_,_,_,id = open_equality e in id
+;;
+
+
let string_of_rule = function
| SuperpositionRight -> "SupR"
| SuperpositionLeft -> "SupL"
function
| Exact _ -> current
| Step (_, (_,id1,(_,id2),_)) ->
- let eq1 = Hashtbl.find id_to_eq id1 in
- let eq2 = Hashtbl.find id_to_eq id2 in
+ let eq1 = M.find id1 id_to_eq in
+ let eq2 = M.find id2 id_to_eq in
let (w1,p1,(_,_,_,_),_,_) = open_equality eq1 in
let (w2,p2,(_,_,_,_),_,_) = open_equality eq2 in
let current = max current w1 in
let max_weight_in_goal_proof ((id_to_eq,_) as bag) =
List.fold_left
(fun current (_,_,id,_,_) ->
- let eq = Hashtbl.find id_to_eq id in
+ let eq = M.find id id_to_eq in
let (w,p,(_,_,_,_),_,_) = open_equality eq in
let current = max current w in
max_weight_in_proof bag current p)
let proof_of_id (id_to_eq,_) id =
try
- let (_,p,(_,l,r,_),_,_) = open_equality (Hashtbl.find id_to_eq id) in
+ let (_,p,(_,l,r,_),_,_) = open_equality (M.find id id_to_eq) in
p,l,r
with
- Not_found -> assert false
+ Not_found ->
+ prerr_endline ("Unable to find the proof of " ^ string_of_int id);
+ assert false
+;;
+
+let is_in (id_to_eq,_) id =
+ M.mem id id_to_eq
+;;
let string_of_proof ?(names=[]) bag p gp =
| Exact _ -> false,seen
| Step (_,(_,id1,(_,id2),_)) ->
let seen = ideq::seen in
- let eq1 = Hashtbl.find id_to_eq id1 in
- let eq2 = Hashtbl.find id_to_eq id2 in
+ let eq1 = M.find id1 id_to_eq in
+ let eq2 = M.find id2 id_to_eq in
let b1,seen = depend bag eq1 id seen in
if b1 then b1,seen else depend bag eq2 id seen
;;
remove_refl p1
| _ -> Cic.Appl (List.map remove_refl args))
| Cic.Appl l -> Cic.Appl (List.map remove_refl l)
- | Cic.LetIn (name,bo,rest) ->
- Cic.LetIn (name,remove_refl bo,remove_refl rest)
+ | Cic.LetIn (name,bo,ty,rest) ->
+ Cic.LetIn (name,remove_refl bo,remove_refl ty,remove_refl rest)
| _ -> t
in
let rec canonical_trough_lambda context = function
and canonical context t =
match t with
- | Cic.LetIn(name,bo,rest) ->
+ | Cic.LetIn(name,bo,ty,rest) ->
let bo = canonical_trough_lambda context bo in
- let context' = (Some (name,Cic.Def (bo,None)))::context in
- Cic.LetIn(name,bo,canonical context' rest)
+ let ty = canonical_trough_lambda context ty in
+ let context' = (Some (name,Cic.Def (bo,ty)))::context in
+ Cic.LetIn(name,bo,ty,canonical context' rest)
| Cic.Appl (((Cic.Const(uri_sym,ens))::tl) as args)
when LibraryObjects.is_sym_eq_URI uri_sym ->
(match p_of_sym ens tl with
when LibraryObjects.is_sym_eq_URI uri_sym ->
let ty,l,r,p = open_sym ens tl in
mk_sym uri_sym ty l r (aux uri ty l r ctx_d ctx_ty p)
- | Cic.LetIn (name,body,rest) ->
- Cic.LetIn (name,look_ahead (aux uri) body, aux uri ty left right ctx_d ctx_ty rest)
+ | Cic.LetIn (name,body,bodyty,rest) ->
+ Cic.LetIn
+ (name,look_ahead (aux uri) body, bodyty,
+ aux uri ty left right ctx_d ctx_ty rest)
| Cic.Appl ((Cic.Const(uri_ind,ens))::tl)
when LibraryObjects.is_eq_ind_URI uri_ind ||
LibraryObjects.is_eq_ind_r_URI uri_ind ->
let string_of_id (id_to_eq,_) names id =
if id = 0 then "" else
try
- let (_,p,(t,l,r,_),m,_) = open_equality (Hashtbl.find id_to_eq id) in
+ let (_,p,(t,l,r,_),m,_) = open_equality (M.find id id_to_eq) in
match p with
| Exact t ->
Printf.sprintf "%d = %s: %s = %s [%s]" id
"\nand then subsumed by " ^ string_of_int id ^ " when " ^ Subst.ppsubst subst
;;
-module OT =
- struct
- type t = int
- let compare = Pervasives.compare
- end
-
-module M = Map.Make(OT)
-
let rec find_deps bag m i =
if M.mem i m then m
else
rc
;;
-
(* returns the list of ids that should be factorized *)
let get_duplicate_step_in_wfo bag l p =
let ol = List.rev l in
aux proof
;;
-let build_goal_proof bag eq l initial ty se context menv =
+let build_goal_proof ?(contextualize=true) ?(forward=false) bag eq l initial ty se context menv =
let se = List.map (fun i -> Cic.Meta (i,[])) se in
let lets = get_duplicate_step_in_wfo bag l initial in
let letsno = List.length lets in
+ let l = if forward then List.rev l else l in
let lift_list l = List.map (fun (i,t) -> i,CicSubstitution.lift 1 t) l in
let lets,_,h =
List.fold_left
acc@[id,real_cic],n+1,h)
([],0,[]) lets
in
+ let lets =
+ List.map (fun (id,cic) -> id,cic,Cic.Implicit (Some `Type)) lets
+ in
let proof,se =
let rec aux se current_proof = function
| [] -> current_proof,se
| (rule,pos,id,subst,pred)::tl ->
let p,l,r = proof_of_id bag id in
let p = build_proof_term bag eq h letsno p in
- let pos = if pos = Utils.Left then Utils.Right else Utils.Left in
+ let pos = if forward then pos else
+ if pos = Utils.Left then Utils.Right else Utils.Left in
let varname =
match rule with
| SuperpositionLeft -> Cic.Name ("SupL" ^ Utils.string_of_pos pos)
let n,proof =
let initial = proof in
List.fold_right
- (fun (id,cic) (n,p) ->
+ (fun (id,cic,ty) (n,p) ->
n-1,
Cic.LetIn (
Cic.Name ("H"^string_of_int id),
- cic, p))
+ cic,
+ ty,
+ p))
lets (letsno-1,initial)
in
- canonical
- (contextualize_rewrites proof (CicSubstitution.lift letsno ty))
- context menv,
- se
+ let proof =
+ if contextualize
+ then contextualize_rewrites proof (CicSubstitution.lift letsno ty)
+ else proof in
+ canonical proof context menv, se
;;
let refl_proof eq_uri ty term =
let irl = [] in
let newmeta = Cic.Meta(maxmeta,irl) in
let newsubst = Subst.buildsubst i context newmeta ty subst in
- newsubst, (maxmeta,context,ty)::metasenv, maxmeta+1)
+ (* newsubst, (maxmeta,context,ty)::metasenv, maxmeta+1) *)
+ newsubst, (maxmeta,[],ty)::metasenv, maxmeta+1)
to_be_relocated (Subst.empty_subst, [], newmeta+1)
in
- let menv = Subst.apply_subst_metasenv subst menv @ newmetasenv in
+ (* let subst = Subst.flatten_subst subst in *)
+ let menv = Subst.apply_subst_metasenv subst (menv @ newmetasenv) in
subst, menv, newmeta
-let fix_metas_goal newmeta goal =
+let fix_metas_goal (id_to_eq,newmeta) goal =
let (proof, menv, ty) = goal in
- let to_be_relocated =
- HExtlib.list_uniq (List.sort Pervasives.compare (Utils.metas_of_term ty))
- in
+ let to_be_relocated = List.map (fun i ,_,_ -> i) menv in
let subst, menv, newmeta = relocate newmeta menv to_be_relocated in
let ty = Subst.apply_subst subst ty in
let proof =
| [] -> assert false (* is a nonsense to relocate the initial goal *)
| (r,pos,id,s,p) :: tl -> (r,pos,id,Subst.concat subst s,p) :: tl
in
- newmeta+1,(proof, menv, ty)
+ (id_to_eq,newmeta+1),(proof, menv, ty)
;;
-let fix_metas bag newmeta eq =
+let fix_metas (id_to_eq, newmeta) eq =
let w, p, (ty, left, right, o), menv,_ = open_equality eq in
- let to_be_relocated =
-(* List.map (fun i ,_,_ -> i) menv *)
- HExtlib.list_uniq
- (List.sort Pervasives.compare
- (Utils.metas_of_term left @ Utils.metas_of_term right @
- Utils.metas_of_term ty))
- in
+ let to_be_relocated = List.map (fun i ,_,_ -> i) menv in
let subst, metasenv, newmeta = relocate newmeta menv to_be_relocated in
let ty = Subst.apply_subst subst ty in
let left = Subst.apply_subst subst left in
Step (Subst.concat s subst,(r,id1,(pos,id2), pred))
in
let p = fix_proof p in
- let eq' = mk_equality bag (w, p, (ty, left, right, o), metasenv) in
- newmeta+1, eq'
+ let bag = id_to_eq, newmeta in
+ let bag, e = mk_equality bag (w, p, (ty, left, right, o), metasenv) in
+ bag, e
+;;
exception NotMetaConvertible;;
aux_ens table ens1 ens2
| C.Cast (s1, t1), C.Cast (s2, t2)
| C.Prod (_, s1, t1), C.Prod (_, s2, t2)
- | C.Lambda (_, s1, t1), C.Lambda (_, s2, t2)
- | C.LetIn (_, s1, t1), C.LetIn (_, s2, t2) ->
+ | C.Lambda (_, s1, t1), C.Lambda (_, s2, t2) ->
let table = aux table s1 s2 in
aux table t1 t2
+ | C.LetIn (_, s1, ty1, t1), C.LetIn (_, s2, ty2, t2) ->
+ let table = aux table s1 s2 in
+ let table = aux table ty1 ty2 in
+ aux table t1 t2
| C.Appl l1, C.Appl l2 -> (
try List.fold_left2 (fun res t1 t2 -> (aux res t1 t2)) table l1 l2
with Invalid_argument _ -> raise NotMetaConvertible
| _ -> false
;;
-let equality_of_term bag proof term =
+let equality_of_term bag proof term newmetas =
match term with
| Cic.Appl [Cic.MutInd (uri, _, _); ty; t1; t2]
when LibraryObjects.is_eq_URI uri ->
let o = !Utils.compare_terms t1 t2 in
let stat = (ty,t1,t2,o) in
let w = Utils.compute_equality_weight stat in
- let e = mk_equality bag (w, Exact proof, stat,[]) in
- e
+ let bag, e = mk_equality bag (w, Exact proof, stat,newmetas) in
+ bag, e
| _ ->
raise TermIsNotAnEquality
;;
Exact (Cic.Appl
[Cic.MutConstruct(uri,0,1,[]);eq_ty;l])
in
- let id1 =
- let eq = mk_equality bag (0,prefl,(eq_ty,l,l,Utils.Eq),m) in
+ let bag, id1 =
+ let bag, eq = mk_equality bag (0,prefl,(eq_ty,l,l,Utils.Eq),m) in
let (_,_,_,_,id) = open_equality eq in
- id
+ bag, id
in
- Step(Subst.empty_subst,
+ bag, Step(Subst.empty_subst,
(Demodulation,id1,(Utils.Left,id),pred))
;;
let n_purged = ref 0;;
-let collect ((id_to_eq,_) as bag) alive1 alive2 alive3 =
-(* let _ = <:start<collect>> in *)
+let collect ((id_to_eq,maxmeta) as bag) alive1 alive2 alive3 =
let deps_of id =
let p,_,_ = proof_of_id bag id in
match p with
let alive_set = l_to_s (l_to_s (l_to_s IntSet.empty alive2) alive1) alive3 in
let closed_alive_set = close alive_set in
let to_purge =
- Hashtbl.fold
+ M.fold
(fun k _ s ->
if not (IntSet.mem k closed_alive_set) then
k::s else s) id_to_eq []
in
n_purged := !n_purged + List.length to_purge;
- List.iter (Hashtbl.remove id_to_eq) to_purge;
-(* let _ = <:stop<collect>> in () *)
-;;
-
-let id_of e =
- let _,_,_,_,id = open_equality e in id
+ List.fold_right M.remove to_purge id_to_eq, maxmeta
;;
let get_stats () = ""
| _ -> assert false
in
let rec skip_letin ctx = function
- | Cic.LetIn (n,b,t) ->
+ | Cic.LetIn (n,b,_,t) ->
pp_proofterm (Some (rename "Lemma " n)) b ctx::
skip_letin ((Some n)::ctx) t
| t ->
when Pcre.pmatch ~pat:"eq_f" (UriManager.string_of_uri uri)->
pp true p
| Cic.Appl [Cic.Const (uri,[]);_;_;_;_;_;p]
- when Pcre.pmatch ~pat:"eq_f1" (UriManager.string_of_uri uri)->
+ when Pcre.pmatch ~pat:"eq_OF_eq" (UriManager.string_of_uri uri)->
pp true p
| Cic.Appl [Cic.MutConstruct (uri,_,_,[]);_;_;t;p]
when Pcre.pmatch ~pat:"ex.ind" (UriManager.string_of_uri uri)->
let string_of_id2 (id_to_eq,_) names nameset id =
if id = 0 then "" else
try
- let (_,_,(_,l,r,_),_,_) = open_equality (Hashtbl.find id_to_eq id) in
+ let (_,_,(_,l,r,_),_,_) = open_equality (M.find id id_to_eq) in
let nameset, l = freshname nameset l in
let nameset, r = freshname nameset r in
Printf.sprintf "%s = %s" (CicPp.pp l names) (CicPp.pp r names)
ignore(Unix.system "gv /tmp/matita_paramod.eps");
;;
+let saturate_term (id_to_eq, maxmeta) metasenv subst context term =
+ let maxmeta = max maxmeta (CicMkImplicit.new_meta metasenv subst) in
+ let head, metasenv, args, newmeta =
+ TermUtil.saturate_term maxmeta metasenv context term 0
+ in
+ (id_to_eq, newmeta), head, metasenv, args
+;;
+
+let push_maxmeta (id_to_eq, maxmeta) m = id_to_eq, max maxmeta m ;;
+let filter_metasenv_gt_maxmeta (_,maxmeta) =
+ List.filter (fun (j,_,_) -> j >= maxmeta)
+;;
+let maxmeta = snd;;