open AutoTypes;;
open AutoCache;;
-let debug = true;;
+let debug = false;;
let debug_print s =
if debug then prerr_endline (Lazy.force s);;
let elems = ref [] ;;
(* closing a term w.r.t. its metavariables
- very naif version: it does not take dependencies into account *)
+ very naif version: it does not take dependencies properly into account *)
-let naif_closure t metasenv context =
+let naif_closure ?(prefix_name="xxx_") t metasenv context =
let metasenv = ProofEngineHelpers.sort_metasenv metasenv in
let n = List.length metasenv in
let what = List.map (fun (i,cc,ty) -> Cic.Meta(i,[])) metasenv in
let _, t =
List.fold_left
(fun (n,t) (_,cc,ty) ->
- n-1, Cic.Lambda(Cic.Name ("x_"^string_of_int n),
+ n-1, Cic.Lambda(Cic.Name (prefix_name^string_of_int n),
CicSubstitution.lift n ty,t))
(n-1,body) metasenv
in
t
;;
+
+let lambda_close ?prefix_name t menv ctx =
+ let t = naif_closure ?prefix_name t menv ctx in
+ List.fold_left
+ (fun (t,i) -> function
+ | None -> CicSubstitution.subst (Cic.Implicit None) t,i (* delift *)
+ | Some (name, Cic.Decl ty) -> Cic.Lambda (name, ty, t),i+1
+ | Some (name, Cic.Def (bo, _)) -> Cic.LetIn (name, bo, t),i+1)
+ (t,List.length menv) ctx
+;;
(* functions for retrieving theorems *)
args
in
if propositional_args = [] then
- let newmetas = List.filter (fun (i,_,_) -> i >= oldnewmeta) metasenv in
+ let newmetas =
+ List.filter (fun (i,_,_) -> i >= oldnewmeta) metasenv
+ in
Some (args,metasenv,newmetas,head,newmeta)
else None
;;
candidates
;;
-let only signature context t =
+let only signature context metasenv t =
try
- let ty,_ = CicTypeChecker.type_of_aux' [] context t CicUniv.empty_ugraph in
+ let ty,_ =
+ CicTypeChecker.type_of_aux' metasenv context t CicUniv.empty_ugraph
+ in
let consts = MetadataConstraints.constants_of ty in
let b = MetadataConstraints.UriManagerSet.subset consts signature in
if b then b
else
- try
- let ty' = unfold context ty in
- let consts' = MetadataConstraints.constants_of ty' in
- MetadataConstraints.UriManagerSet.subset consts' signature
- with _-> false
- with _ -> false
+ let ty' = unfold context ty in
+ let consts' = MetadataConstraints.constants_of ty' in
+ MetadataConstraints.UriManagerSet.subset consts' signature
+ with
+ | CicTypeChecker.TypeCheckerFailure _ -> assert false
+ | ProofEngineTypes.Fail _ -> false (* unfold may fail *)
;;
let not_default_eq_term t =
not (LibraryObjects.in_eq_URIs uri)
with Invalid_argument _ -> true
-let retrieve_equations signature universe cache context=
+let retrieve_equations dont_filter signature universe cache context metasenv =
match LibraryObjects.eq_URI() with
| None -> []
| Some eq_uri ->
let fake= Cic.Meta(-1,[]) in
let fake_eq = Cic.Appl [Cic.MutInd (eq_uri,0, []);fake;fake;fake] in
let candidates = get_candidates universe cache fake_eq in
- (* defaults eq uris are built-in in auto *)
- let candidates = List.filter not_default_eq_term candidates in
- let candidates = List.filter (only signature context) candidates in
- List.iter (fun t -> debug_print (lazy (CicPp.ppterm t))) candidates;
- candidates
+ if dont_filter then candidates
+ else
+ let candidates = List.filter not_default_eq_term candidates in
+ List.filter (only signature context metasenv) candidates
let build_equality bag head args proof newmetas maxmeta =
match head with
let partition_unit_equalities context metasenv newmeta bag equations =
List.fold_left
(fun (units,other,maxmeta)(t,ty) ->
+ if not (CicUtil.is_meta_closed t && CicUtil.is_meta_closed ty) then
+ let _ =
+ HLog.warn
+ ("Skipping " ^ CicMetaSubst.ppterm_in_context ~metasenv [] t context
+ ^ " since it is not meta closed")
+ in
+ units,(t,ty)::other,maxmeta
+ else
match is_unit_equation context metasenv maxmeta ty with
| Some (args,metasenv,newmetas,head,newmeta') ->
let maxmeta,equality =
Saturation.make_passive [],
Equality.mk_equality_bag)
-let init_cache_and_tables dbd use_library paramod universe (proof, goal) =
+let init_cache_and_tables
+ ?dbd use_library paramod use_context dont_filter universe (proof, goal)
+=
(* the local cache in initially empty *)
let cache = AutoCache.cache_empty in
- let _, metasenv, _, _, _ = proof in
+ let _, metasenv, _subst,_, _, _ = proof in
let signature = MetadataQuery.signature_of metasenv goal in
let newmeta = CicMkImplicit.new_meta metasenv [] in
let _,context,_ = CicUtil.lookup_meta goal metasenv in
- let ct = find_context_theorems context metasenv in
+ let ct = if use_context then find_context_theorems context metasenv else [] in
debug_print
(lazy ("ho trovato nel contesto " ^ (string_of_int (List.length ct))));
let lt =
- if use_library then
- find_library_theorems dbd metasenv goal
- else [] in
+ match use_library, dbd with
+ | true, Some dbd -> find_library_theorems dbd metasenv goal
+ | _ -> []
+ in
debug_print
(lazy ("ho trovato nella libreria " ^ (string_of_int (List.length lt))));
let cache = cache_add_list cache context (ct@lt) in
let equations =
- retrieve_equations signature universe cache context in
+ retrieve_equations dont_filter signature universe cache context metasenv
+ in
debug_print
(lazy ("ho trovato equazioni n. "^(string_of_int (List.length equations))));
let eqs_and_types =
HExtlib.filter_map
(fun t ->
let ty,_ =
- CicTypeChecker.type_of_aux' metasenv context t CicUniv.empty_ugraph in
- (* retrieve_equations could also return flexible terms *)
- if is_an_equality ty then Some(t,ty)
- else
- try
- let ty' = unfold context ty in
- if is_an_equality ty' then Some(t,ty') else None
- with _ -> None) (* catturare l'eccezione giusta di unfold *)
- equations in
+ CicTypeChecker.type_of_aux'
+ metasenv context t CicUniv.empty_ugraph
+ in
+ (* retrieve_equations could also return flexible terms *)
+ if is_an_equality ty then Some(t,ty)
+ else
+ try
+ let ty' = unfold context ty in
+ if is_an_equality ty' then Some(t,ty') else None
+ with _ -> None) (* catturare l'eccezione giusta di unfold *)
+ equations
+ in
let bag = Equality.mk_equality_bag () in
let units, other_equalities, newmeta =
- partition_unit_equalities context metasenv newmeta bag eqs_and_types in
- (* let env = (metasenv, context, CicUniv.empty_ugraph) in
- let equalities =
- let eq_uri =
- match LibraryObjects.eq_URI() with
- | None ->assert false
- | Some eq_uri -> eq_uri in
- Saturation.simplify_equalities bag eq_uri env units in *)
+ partition_unit_equalities context metasenv newmeta bag eqs_and_types
+ in
+ (* SIMPLIFICATION STEP
+ let equalities =
+ let env = (metasenv, context, CicUniv.empty_ugraph) in
+ let eq_uri = HExtlib.unopt (LibraryObjects.eq_URI()) in
+ Saturation.simplify_equalities bag eq_uri env units
+ in
+ *)
let passive = Saturation.make_passive units in
let no = List.length units in
let active = Saturation.make_active [] in
let close_more tables maxmeta context status auto universe cache =
let (active,passive,bag) = tables in
let proof, goalno = status in
- let _, metasenv,_,_, _ = proof in
+ let _, metasenv,_subst,_,_, _ = proof in
let signature = MetadataQuery.signature_of metasenv goalno in
- let equations = retrieve_equations signature universe cache context in
+ let equations =
+ retrieve_equations false signature universe cache context metasenv
+ in
let eqs_and_types =
HExtlib.filter_map
(fun t ->
let module C = Cic in
let module S = CicSubstitution in
let module T = CicTypeChecker in
- let _,metasenv,_,_, _ = proof in
+ let _,metasenv,_subst,_,_, _ = proof in
let newmeta = max (ProofEngineHelpers.new_meta_of_proof ~proof) maxmeta in
(* if use_auto is true, we try to close the hypothesis of equational
statements using auto; a naif, and probably wrong approach *)
match arguments with [] -> term' | _ -> Cic.Appl (term'::arguments)
in
let proof',oldmetasenv =
- let (puri,metasenv,pbo,pty, attrs) = proof in
- (puri,newmetasenv,pbo,pty, attrs),metasenv
+ let (puri,metasenv,_subst,pbo,pty, attrs) = proof in
+ (puri,newmetasenv,_subst,pbo,pty, attrs),metasenv
in
let goal_for_paramod =
match LibraryObjects.eq_URI () with
in
let newmeta = CicMkImplicit.new_meta newmetasenv (*subst*) [] in
let metasenv_for_paramod = (newmeta,context,goal_for_paramod)::newmetasenv in
- let proof'' = let uri,_,p,ty, attrs = proof' in uri,metasenv_for_paramod,p,ty, attrs in
+ let proof'' =
+ let uri,_,_subst,p,ty, attrs = proof' in
+ uri,metasenv_for_paramod,_subst,p,ty, attrs
+ in
let irl = CicMkImplicit.identity_relocation_list_for_metavariable context in
let proof''',goals =
ProofEngineTypes.apply_tactic
(proof'',goal)
in
let goal = match goals with [g] -> g | _ -> assert false in
- let subst, (proof'''', _), _ =
- PrimitiveTactics.apply_with_subst ~term:term'' ~subst:[] (proof''',goal)
+ let proof'''', _ =
+ ProofEngineTypes.apply_tactic
+ (PrimitiveTactics.apply_tac term'')
+ (proof''',goal)
in
match
let (active, passive,bag), cache, maxmeta =
- init_cache_and_tables dbd flags.use_library true universe (proof'''',newmeta)
+ init_cache_and_tables ~dbd flags.use_library true true false universe
+ (proof'''',newmeta)
in
Saturation.given_clause bag maxmeta (proof'''',newmeta) active passive
max_int max_int flags.timeout
| None, _,_,_ ->
raise (ProofEngineTypes.Fail (lazy ("FIXME: propaga le tabelle")))
| Some (_,proof''''',_), active,passive,_ ->
- subst,proof''''',
+ proof''''',
ProofEngineHelpers.compare_metasenvs ~oldmetasenv
- ~newmetasenv:(let _,m,_,_, _ = proof''''' in m), active, passive
+ ~newmetasenv:(let _,m,_subst,_,_, _ = proof''''' in m), active, passive
;;
let rec count_prods context ty =
let module T = CicTypeChecker in
let module R = CicReduction in
let module C = Cic in
- let (_,metasenv,_,_, _) = proof in
+ let (_,metasenv,_subst,_,_, _) = proof in
let metano,context,ty = CicUtil.lookup_meta goal metasenv in
let newmeta = CicMkImplicit.new_meta metasenv subst in
let exp_named_subst_diff,newmeta',newmetasenvfragment,term' =
in
let termty = CicSubstitution.subst_vars exp_named_subst_diff termty in
let goal_arity = count_prods context ty in
- let subst, proof, gl, active, passive =
+ let proof, gl, active, passive =
new_metasenv_and_unify_and_t dbd flags universe proof goal ?tables
newmeta' metasenv' context term' ty termty goal_arity
in
- subst, proof, gl, active, passive
+ proof, gl, active, passive
;;
(****************** AUTO ********************)
* step *)
| S of goal * AutoCache.cache_key * candidate * int
type elem =
- (* menv, subst, size, operations to do, failures to cache if any op fails *)
- menv * subst * int * op list * fail list
+ (* menv, subst, size, operations done (only S), operations to do, failures to cache if any op fails *)
+ menv * subst * int * op list * op list * fail list
type status =
(* list of computations that may lead to the solution: all op list will
* end with the same (S(g,_)) *)
(* the status exported to the external observer *)
type auto_status =
(* context, (goal,candidate) list, and_list, history *)
- Cic.context * (Cic.term * (int * Cic.term) list) list *
- Cic.term list * Cic.term list
+ Cic.context * (int * Cic.term * bool * int * (int * Cic.term) list) list *
+ (int * Cic.term * int) list * Cic.term list
let d_prefix l =
let rec aux acc = function
in
let rec aux = function
| [] -> ()
- | (m,s,ol,fl)::tl ->
+ | (m,s,_,_,ol,fl)::tl ->
Printf.eprintf "< [%s] ;;; [%s]>\n"
(string_of_ol m s ol) (string_of_fl m s fl);
aux tl
let cond = Condition.create ();;
let mutex = Mutex.create ();;
let hint = ref None;;
+let prune_hint = ref [];;
let step _ = Condition.signal cond;;
let give_hint n = hint := Some n;;
+let give_prune_hint hint =
+ prune_hint := hint :: !prune_hint
+;;
let check_pause _ =
if !in_pause then
let get_auto_status _ =
let status = !auto_status in
-(*
- debug_print "status:";
- List.iter (fun ((cand,ty),_,_,gl) ->
- Printf.eprintf "cand: %s; ty: %s; gl: %d\n"
- (CicPp.ppterm cand) (CicPp.ppterm ty) (List.length gl)) status;
-*)
let and_list,elems,last =
match status with
| [] -> [],[],[]
- | (m,s,_,gl,fail)::tl ->
+ | (m,s,_,don,gl,fail)::tl ->
let and_list =
- List.map snd
- (HExtlib.filter_map
- (fun g -> calculate_goal_ty g s m) (d_goals gl))
+ HExtlib.filter_map
+ (fun (id,d,_ as g) ->
+ match calculate_goal_ty g s m with
+ | Some (_,x) -> Some (id,x,d) | None -> None)
+ (d_goals gl)
in
let rows =
(* these are the S goalsin the or list *)
let orlist =
List.map
- (fun (m,s,_,gl,fail) ->
+ (fun (m,s,_,don,gl,fail) ->
HExtlib.filter_map
- (function S (g,k,c,_) -> Some (g,k,c) | _ -> None) gl)
+ (function S (g,k,c,_) -> Some (g,k,c) | _ -> None)
+ (List.rev don @ gl))
status
in
(* this function eats id from a list l::[id,x] returning x, l *)
let eat_tail_if_eq id l =
- match (List.rev l) with
- | ((id1,_,_),k1,c)::tl when id = id1 -> Some c, List.rev tl
- | _ -> None, l
+ let rec aux (s, l) = function
+ | [] -> s, l
+ | ((id1,_,_),k1,c)::tl when id = id1 ->
+ (match s with
+ | None -> aux (Some c,l) tl
+ | Some _ -> assert false)
+ | ((id1,_,_),k1,c as e)::tl -> aux (s, e::l) tl
+ in
+ let c, l = aux (None, []) l in
+ c, List.rev l
in
let eat_in_parallel id l =
- let rec aux (eaten, new_l as acc) l =
+ let rec aux (b,eaten, new_l as acc) l =
match l with
| [] -> acc
| l::tl ->
match eat_tail_if_eq id l with
- | None, l -> aux (eaten, new_l@[l]) tl
- | Some t,l -> aux (eaten@[t], new_l@[l]) tl
+ | None, l -> aux (b@[false], eaten, new_l@[l]) tl
+ | Some t,l -> aux (b@[true],eaten@[t], new_l@[l]) tl
in
- aux ([],[]) l
+ aux ([],[],[]) l
in
let rec eat_all rows l =
match l with
| [] -> rows
| elem::or_list ->
match List.rev elem with
- | ((to_eat,_,_),k,_)::next_lunch ->
- let eaten, l = eat_in_parallel to_eat l in
+ | ((to_eat,depth,_),k,_)::next_lunch ->
+ let b, eaten, l = eat_in_parallel to_eat l in
let eaten = HExtlib.list_uniq eaten in
- let rows = rows @ [k,eaten] in
+ let eaten = List.rev eaten in
+ let b = true (* List.hd (List.rev b) *) in
+ let rows = rows @ [to_eat,k,b,depth,eaten] in
eat_all rows l
| [] -> eat_all rows or_list
in
- eat_all [] orlist
+ eat_all [] (List.rev orlist)
in
let history =
HExtlib.filter_map
let eat_head todo id fl orlist =
let rec aux acc = function
| [] -> [], acc
- | (m, s, _, todo1, fl1)::tl as orlist ->
+ | (m, s, _, _, todo1, fl1)::tl as orlist ->
let rec aux1 todo1 =
match first_s todo1 with
| None -> orlist, acc
else (* cache_add_success cache key closed_proof *)
(debug_print (lazy ("NO CACHE: (no gree proof)"));cache)
in
- cache, orlist, fl
+ cache, orlist, fl, true
else
let cache =
debug_print (lazy ("TENTATIVE CACHE: " ^ CicPp.ppterm gty));
| CicTypeChecker.TypeCheckerFailure _ ->*)
(debug_print (lazy ("NO CACHE: (no green gty )"));cache)
in
- cache, orlist, fl
+ cache, orlist, fl, false
;;
let close_failures (fl : fail list) (cache : cache) =
List.fold_left
let metasenv = CicMetaSubst.apply_subst_metasenv subst metasenv in
subst, metasenv
;;
-let mk_fake_proof metasenv (goalno,_,_) goalty context =
- None,metasenv,Cic.Meta(goalno,mk_irl context),goalty, []
+let mk_fake_proof metasenv subst (goalno,_,_) goalty context =
+ None,metasenv,subst ,Cic.Meta(goalno,mk_irl context),goalty, []
;;
let equational_case
tables maxm cache depth fake_proof goalno goalty subst context
with
| None, active, passive, maxmeta ->
[], (active,passive,bag), cache, maxmeta, flags
- | Some(subst',(_,metasenv,proof,_, _),open_goals),active,
+ | Some(subst',(_,metasenv,_subst,proof,_, _),open_goals),active,
passive,maxmeta ->
assert_subst_are_disjoint subst subst';
let subst = subst@subst' in
assert (maxmeta >= maxm);
let res' =
List.map
- (fun subst',(_,metasenv,proof,_, _),open_goals ->
+ (fun (subst',(_,metasenv,_subst,proof,_, _),open_goals) ->
assert_subst_are_disjoint subst subst';
let subst = subst@subst' in
let open_goals =
=
let ppterm = ppterm context in
try
- let subst', ((_,metasenv,_,_, _), open_goals), maxmeta =
- PrimitiveTactics.apply_with_subst
- ~maxmeta:maxm ~term:cand ~subst (fake_proof,goalno)
+ let subst,((_,metasenv,_,_,_,_), open_goals),maxmeta =
+ (PrimitiveTactics.apply_with_subst ~subst ~maxmeta:maxm ~term:cand)
+ (fake_proof,goalno)
in
debug_print (lazy (" OK: " ^ ppterm cand));
let metasenv = CicRefine.pack_coercion_metasenv metasenv in
- let subst = subst' in
let open_goals = order_new_goals metasenv subst open_goals ppterm in
let open_goals = List.map (fun (x,sort) -> x,depth-1,sort) open_goals in
incr candidate_no;
;;
let sort_new_elems =
- List.sort (fun (_,_,_,l1) (_,_,_,l2) -> List.length l1 - List.length l2)
+ List.sort (fun (_,_,_,l1) (_,_,_,l2) ->
+ List.length (prop_only l1) - List.length (prop_only l2))
;;
let applicative_case
universe flags m s g gty tables cache maxm context
=
let goalno, depth, sort = g in
- let fake_proof = mk_fake_proof m g gty context in
+ let fake_proof = mk_fake_proof m s g gty context in
if is_equational_case gty flags then
let elems,tables,cache,maxm1, flags =
equational_case tables maxm cache
in
elems, tables, cache, maxm, flags
;;
-let rec first_s_cand = function
- | [] -> 0
- | S (_,_,(i,_),_):: _ -> i
- | _::tl -> first_s_cand tl
+let rec condition_for_hint i = function
+ | [] -> false
+ | S (_,_,(j,_),_):: tl -> j <> i (* && condition_for_hint i tl *)
+ | _::tl -> condition_for_hint i tl
;;
let remove_s_from_fl (id,_,_) (fl : fail list) =
let rec aux = function
in
aux fl
;;
+
+let prunable_for_size flags s m todo =
+ let rec aux b = function
+ | (S _)::tl -> aux b tl
+ | (D (_,_,T))::tl -> aux b tl
+ | (D g)::tl ->
+ (match calculate_goal_ty g s m with
+ | None -> aux b tl
+ | Some (canonical_ctx, gty) ->
+ let gsize, _ =
+ Utils.weight_of_term
+ ~consider_metas:false ~count_metas_occurrences:true gty in
+ let newb = b || gsize > flags.maxgoalsizefactor in
+ aux newb tl)
+ | [] -> b
+ in
+ aux false todo
+
+(*
+let prunable ty todo =
+ let rec aux b = function
+ | (S(_,k,_,_))::tl -> aux (b || Equality.meta_convertibility k ty) tl
+ | (D (_,_,T))::tl -> aux b tl
+ | D _::_ -> false
+ | [] -> b
+ in
+ aux false todo
+;;
+*)
+
+let prunable menv subst ty todo =
+ let rec aux = function
+ | (S(_,k,_,_))::tl ->
+ (match Equality.meta_convertibility_subst k ty menv with
+ | None -> aux tl
+ | Some variant ->
+ no_progress variant tl (* || aux tl*))
+ | (D (_,_,T))::tl -> aux tl
+ | _ -> false
+ and no_progress variant = function
+ | [] -> prerr_endline "++++++++++++++++++++++++ no_progress"; true
+ | D ((n,_,P) as g)::tl ->
+ (match calculate_goal_ty g subst menv with
+ | None -> no_progress variant tl
+ | Some (_, gty) ->
+ (match calculate_goal_ty g variant menv with
+ | None -> assert false
+ | Some (_, gty') ->
+ if gty = gty' then
+ no_progress variant tl
+ else false))
+ | _::tl -> no_progress variant tl
+ in
+ aux todo
+
+;;
+let condition_for_prune_hint prune (m, s, size, don, todo, fl) =
+ let s =
+ HExtlib.filter_map (function S (_,_,(c,_),_) -> Some c | _ -> None) todo
+ in
+ List.for_all (fun i -> List.for_all (fun j -> i<>j) prune) s
+;;
+let filter_prune_hint l =
+ let prune = !prune_hint in
+ prune_hint := []; (* possible race... *)
+ if prune = [] then l
+ else List.filter (condition_for_prune_hint prune) l
+;;
let auto_main tables maxm context flags universe cache elems =
auto_context := context;
let rec aux tables maxm flags cache (elems : status) =
-(* pp_status context elems; *)
+(* pp_status context elems; *)
+(* DEBUGGING CODE: uncomment these two lines to stop execution at each iteration
+ auto_status := elems;
+ check_pause ();
+*)
+ let elems = filter_prune_hint elems in
match elems with
+ | (m, s, size, don, todo, fl)::orlist when !hint <> None ->
+ (match !hint with
+ | Some i when condition_for_hint i todo ->
+ aux tables maxm flags cache orlist
+ | _ ->
+ hint := None;
+ aux tables maxm flags cache elems)
| [] ->
(* complete failure *)
Gaveup (tables, cache, maxm)
- | (m, s, _, [],_)::orlist ->
+ | (m, s, _, _, [],_)::orlist ->
(* complete success *)
Proved (m, s, orlist, tables, cache, maxm)
- | (m, s, size, (D (_,_,T))::todo, fl)::orlist ->
+ | (m, s, size, don, (D (_,_,T))::todo, fl)::orlist ->
(* skip since not Prop, don't even check if closed by side-effect *)
- aux tables maxm flags cache ((m, s, size, todo, fl)::orlist)
- | (m, s, size, (S(g, key, c,minsize))::todo, fl)::orlist ->
+ aux tables maxm flags cache ((m, s, size, don, todo, fl)::orlist)
+ | (m, s, size, don, (S(g, key, c,minsize) as op)::todo, fl)::orlist ->
(* partial success, cache g and go on *)
- let cache, orlist, fl =
+ let cache, orlist, fl, sibling_pruned =
add_to_cache_and_del_from_orlist_if_green_cut
g s m cache key todo orlist fl context size minsize
in
debug_print (lazy (AutoCache.cache_print context cache));
let fl = remove_s_from_fl g fl in
- aux tables maxm flags cache ((m, s, size, todo, fl)::orlist)
- | (m, s, size, todo, fl)::orlist
+ let don = if sibling_pruned then don else op::don in
+ aux tables maxm flags cache ((m, s, size, don, todo, fl)::orlist)
+ | (m, s, size, don, todo, fl)::orlist
when List.length(prop_only (d_goals todo)) > flags.maxwidth ->
debug_print (lazy ("FAIL: WIDTH"));
(* too many goals in and generated by last th *)
let cache = close_failures fl cache in
aux tables maxm flags cache orlist
- | (m, s, size, todo, fl)::orlist
- when size > flags.maxsize ->
- debug_print (lazy ("FAIL: SIZE"));
+ | (m, s, size, don, todo, fl)::orlist when size > flags.maxsize ->
+ debug_print
+ (lazy ("FAIL: SIZE: "^string_of_int size ^
+ " > " ^ string_of_int flags.maxsize ));
(* we already have a too large proof term *)
let cache = close_failures fl cache in
aux tables maxm flags cache orlist
| _ when Unix.gettimeofday () > flags.timeout ->
(* timeout *)
- debug_print (lazy ("FAIL: SIZE"));
+ debug_print (lazy ("FAIL: TIMEOUT"));
Gaveup (tables, cache, maxm)
- | (m, s, size, (D (gno,depth,P as g))::todo, fl)::orlist as status ->
+ | (m, s, size, don, (D (gno,depth,P as g))::todo, fl)::orlist as status ->
(* attack g *)
match calculate_goal_ty g s m with
| None ->
(* closed by side effect *)
debug_print (lazy ("SUCCESS: SIDE EFFECT: " ^ string_of_int gno));
- aux tables maxm flags cache ((m,s,size,todo, fl)::orlist)
+ aux tables maxm flags cache ((m,s,size,don,todo, fl)::orlist)
| Some (canonical_ctx, gty) ->
+ let gsize, _ =
+ Utils.weight_of_term ~consider_metas:false ~count_metas_occurrences:true gty
+ in
+ if gsize > flags.maxgoalsizefactor then
+ (debug_print (lazy ("FAIL: SIZE: goal: "^string_of_int gsize));
+ aux tables maxm flags cache orlist)
+ else if prunable_for_size flags s m todo then
+ (prerr_endline ("POTO at depth: "^(string_of_int depth));
+ aux tables maxm flags cache orlist)
+ else
(* still to be proved *)
- debug_print (lazy ("EXAMINE: "^CicPp.ppterm gty));
- debug_print (lazy (AutoCache.cache_print context cache));
+ (debug_print (lazy ("EXAMINE: "^CicPp.ppterm gty));
match cache_examine cache gty with
| Failed_in d when d >= depth ->
(* fail depth *)
| Succeded t ->
debug_print (lazy ("SUCCESS: CACHE HIT: " ^ string_of_int gno));
let s, m = put_in_subst s m g canonical_ctx t gty in
- aux tables maxm flags cache ((m, s, size, todo, fl)::orlist)
+ aux tables maxm flags cache ((m, s, size, don,todo, fl)::orlist)
| Notfound
| Failed_in _ when depth > 0 ->
- (match !hint with
- | Some i when first_s_cand todo <> i ->
- aux tables maxm flags cache orlist
- | _ -> hint := None;
- (* more depth or is the first time we see the goal *)
+ ( (* more depth or is the first time we see the goal *)
+ if prunable m s gty todo then
+ (debug_print (lazy(
+ "FAIL: LOOP: one father is equal"));
+ aux tables maxm flags cache orlist)
+ else
let cache = cache_add_underinspection cache gty depth in
auto_status := status;
check_pause ();
debug_print
(lazy ("INSPECTING: " ^
- string_of_int gno ^ "("^ string_of_int size ^ "): "^CicPp.ppterm gty));
+ string_of_int gno ^ "("^ string_of_int size ^ "): "^
+ CicPp.ppterm gty));
(* elems are possible computations for proving gty *)
let elems, tables, cache, maxm, flags =
equational_and_applicative_case
| [] -> assert false
| (cand,m,s,gl)::[] ->
(* in the last one we add the failure *)
- let todo = inj_gl gl @ (S(g,gty,cand,size+1))::todo in
+ let todo =
+ inj_gl gl @ (S(g,gty,cand,size+1))::todo
+ in
(* we are the last in OR, we fail on g and
* also on all failures implied by g *)
- (m,s, size + size_gl gl, todo, (g,gty)::fl) :: orlist
+ (m,s, size + size_gl gl, don, todo, (g,gty)::fl)
+ :: orlist
| (cand,m,s,gl)::tl ->
(* we add the S step after gl and before todo *)
- let todo = inj_gl gl @ (S(g,gty,cand,size+1))::todo in
+ let todo =
+ inj_gl gl @ (S(g,gty,cand,size+1))::todo
+ in
(* since we are not the last in OR, we do not
* imply failures *)
- (m,s, size + size_gl gl, todo, []) :: map tl
+ (m,s, size + size_gl gl, don, todo, []) :: map tl
in
map elems
in
(* no more depth *)
debug_print (lazy ("FAIL: DEPTH: " ^ string_of_int gno));
let cache = close_failures fl cache in
- aux tables maxm flags cache orlist
+ aux tables maxm flags cache orlist)
in
(aux tables maxm flags cache elems : auto_result)
;;
-(*
-let rec auto_main tables maxm context flags elems universe cache =
- auto_context := context;
- let flags = calculate_timeout flags in
- let ppterm = ppterm context in
- let irl = mk_irl context in
- let rec aux flags tables maxm cache elems status =
- match elems with (* elems in OR *)
- | [] -> Fail "no more steps can be done", tables, cache, maxm
- (*COMPLETE FAILURE*)
- | (p ,metasenv,subst,[])::tl ->
- Success (p,metasenv,subst,tl), tables, cache,maxm (* solution::cont *)
- | (_,metasenv,subst,goals)::tl when
- List.length (List.filter prop goals) > flags.maxwidth ->
- debug_print
- (lazy (" FAILURE(width): " ^ string_of_int (List.length goals)));
- aux flags tables maxm cache tl (List.tl status) (* FAILURE (width) *)
- | (p,metasenv,subst,((goalno,depth,sort) as elem)::gl)::tl ->
- let (_,_,_,_::gl_status)::tl_status = status in
- if Unix.gettimeofday() > flags.timeout then
- Fail "timeout",tables,cache,maxm
- else
- try
- let _,cc,goalty = CicUtil.lookup_meta goalno metasenv in
- let id,_,_ = p in
- debug_print
- (lazy ("INSPECTING " ^ string_of_int goalno^
- ":"^"(id="^string_of_int id^")"^ppterm goalty ^
- "with depth"^string_of_int depth));
- debug_print (lazy (AutoCache.cache_print context cache));
- if sort = T (* && tl <> []*) then
- (debug_print
- (lazy (" FAILURE(not in prop)"));
- aux flags tables maxm cache ((p,metasenv,subst,gl)::tl)
- ((p,metasenv,subst,gl)::tl_status))
- else
- match aux_single flags tables maxm universe cache metasenv subst elem
- goalty cc gl_status tl_status p with
- | Fail s, tables, cache, maxm' ->
- let maxm = maxm' in
- debug_print
- (lazy
- (" FAIL "^s^": "^string_of_int goalno^":"^ppterm goalty));
- let cache =
- if flags.dont_cache_failures or s = "hint" then
- cache_remove_underinspection cache goalty
- else
- cache_add_failure cache goalty depth
- in
- aux flags tables maxm cache tl tl_status
- | Success (p1,metasenv,subst,others), tables, cache, maxm' ->
- let maxm = maxm' in
- (* others are alternatives in OR *)
- try
- let goal = Cic.Meta(goalno,irl) in
- let proof = CicMetaSubst.apply_subst subst goal in
- debug_print
- (lazy ("DONE: " ^ ppterm goalty^" with: "^ppterm proof));
- if is_a_green_cut goalty then
- (* assert_proof_is_valid proof metasenv context goalty; *)
- let cache = cache_add_success sort cache goalty proof in
- aux flags tables maxm cache ((p,metasenv,subst,gl)::tl)
- ((p,metasenv,subst,gl)::tl_status)
-
- else
- (let goalty = CicMetaSubst.apply_subst subst goalty in
- (* assert_proof_is_valid proof metasenv context goalty; *)
- let cache =
- if is_a_green_cut goalty then
- cache_add_success sort cache goalty proof
- else
- cache
- in
- let others =
- List.map
- (fun (p,metasenv,subst,goals) ->
- (p,metasenv,subst,goals@gl))
- others
- in
- aux flags tables maxm cache
- ((p,metasenv,subst,gl)::others@tl)
- ((p,metasenv,subst,gl)::others@tl_status)
-
- )
-
- with CicUtil.Meta_not_found i when i = goalno ->
- assert false
- with CicUtil.Meta_not_found i when i = goalno ->
- (* goalno was closed by sideeffect *)
- debug_print
- (lazy ("Goal "^string_of_int goalno^" closed by sideeffect"));
- aux flags tables maxm cache ((p,metasenv,subst,gl)::tl)
- ((p,metasenv,subst,gl)::tl_status)
-
- and aux_single flags tables maxm universe cache metasenv subst (goalno, depth,
- _) goalty cc e l (id,_,_) =
- match !hint with
- | Some id' when id <> id' -> Fail "hint", tables,cache,maxm
- | _ ->
- hint := None;
- (* let flags = if depth < 10 then {flags with maxwidth=3} else flags in *)
- let goalty = CicMetaSubst.apply_subst subst goalty in
-(* else if not (is_in_prop context subst metasenv goalty) then Fail,cache *)
- (* FAILURE (euristic cut) *)
- match cache_examine cache goalty with
- | Failed_in d when d >= depth ->
- Fail ("depth " ^ string_of_int d ^ ">=" ^ string_of_int depth),
- tables,cache,maxm(*FAILURE(depth)*)
- | Succeded t ->
- let entry = goalno, (cc, t,goalty) in
- assert_subst_are_disjoint subst [entry];
- let subst = entry :: subst in
- let metasenv = CicMetaSubst.apply_subst_metasenv subst metasenv in
- debug_print (lazy (" CACHE HIT!"));
- incr candidate_no;
- Success ((!candidate_no,t,goalty),metasenv, subst, []), tables, cache, maxm
- | UnderInspection ->
- (* assert (not (is_a_green_cut goalty)); *)
- Fail "looping",tables,cache, maxm
- | Notfound
- | Failed_in _ when depth > 0 -> (* we have more depth now *)
- let cache = cache_add_underinspection cache goalty depth in
- let fake_proof = None,metasenv,Cic.Meta(goalno,irl),goalty, [] in (* FG: attrs *)
- let elems, tables, cache, maxm, flags =
- if is_equational_case goalty flags then
- let elems,tables,cache,maxm1, flags =
- equational_case tables maxm cache
- depth fake_proof goalno goalty subst context flags in
- let maxm = maxm1 in
- let more_elems, tables, cache, maxm1 =
- if flags.use_only_paramod then
- [],tables, cache, maxm
- else
- applicative_case
- tables maxm depth subst fake_proof goalno
- goalty metasenv context universe cache in
- let maxm = maxm1 in
- elems@more_elems, tables, cache, maxm, flags
- else
- let elems, tables, cache, maxm =
- applicative_case tables maxm depth subst fake_proof goalno
- goalty metasenv context universe cache in
- elems, tables, cache, maxm, flags
- in
- let status =
- List.map (fun (p,m,s,l) -> p,m,s,l@e) elems @ l
- in
- auto_status := status;
- check_pause ();
- let rc = aux flags tables maxm cache elems status in
- debug_print "BACK!";
- rc
- | _ -> Fail "depth = 0",tables,cache,maxm
- in
- aux flags tables maxm cache elems elems
-and
-*)
-
-(*
-let
- auto_all_solutions maxm tables universe cache context metasenv gl flags
-=
- let goals = order_new_goals metasenv [] gl CicPp.ppterm in
- let goals = List.map (fun (x,s) -> x,flags.maxdepth,s) goals in
- let elems = [(0,Cic.Implicit None,Cic.Implicit None), metasenv,[],goals] in
- let rec aux tables maxm solutions cache elems flags =
- match auto_main tables maxm context flags elems universe cache with
- | Fail s,tables,cache,maxm ->debug_print s; solutions,cache,maxm
- | Success (_,metasenv,subst,others),tables,cache,maxm ->
- if Unix.gettimeofday () > flags.timeout then
- ((subst,metasenv)::solutions), cache, maxm
- else
- aux tables maxm ((subst,metasenv)::solutions) cache others flags
- in
- let rc = aux tables maxm [] cache elems flags in
- match rc with
- | [],cache,maxm -> [],cache,maxm
- | solutions,cache,maxm ->
- let solutions =
- HExtlib.filter_map
- (fun (subst,newmetasenv) ->
- let opened =
- ProofEngineHelpers.compare_metasenvs ~oldmetasenv:metasenv ~newmetasenv
- in
- if opened = [] then Some subst else None)
- solutions
- in
- solutions,cache,maxm
-;;
-*)
let
auto_all_solutions maxm tables universe cache context metasenv gl flags
=
List.map
(fun (x,s) -> D (x,flags.maxdepth,s)) goals
in
- let elems = [metasenv,[],1,goals,[]] in
+ let elems = [metasenv,[],1,[],goals,[]] in
let rec aux tables maxm solutions cache elems flags =
match auto_main tables maxm context flags universe cache elems with
| Gaveup (tables,cache,maxm) ->
(* }}} ****************** AUTO ***************)
-(* script generation for applicative proofs
-let cic2grafite context menv t =
- let module PT = CicNotationPt in
- let module GA = GrafiteAst in
- let pp_t context t =
- let names = Utils.names_of_context context in
- CicPp.pp t names
- in
- let sort_of context t =
- let ty,_ =
- CicTypeChecker.type_of_aux' menv context t
- CicUniv.oblivion_ugraph
- in
- let sort,_ = CicTypeChecker.type_of_aux' menv context ty
- CicUniv.oblivion_ugraph
- in
- match sort with
- | Cic.Sort Cic.Prop -> P
- | _ -> T
- in
- let floc = HExtlib.dummy_floc in
- let rec print_term c = function
- | Cic.Rel _
- | Cic.MutConstruct _
- | Cic.MutInd _
- | Cic.Const _ as t ->
- PT.Ident (pp_t c t, None)
- | Cic.Appl l -> PT.Appl (List.map (print_term c) l)
- | Cic.Implicit _ -> PT.Implicit
- | Cic.Lambda (Cic.Name n, s, t) ->
- PT.Binder (`Lambda, (PT.Ident (n,None), Some (print_term c s)),
- print_term (Some (Cic.Name n, Cic.Decl s)::c) t)
- | Cic.Prod (Cic.Name n, s, t) ->
- PT.Binder (`Forall, (PT.Ident (n,None), Some (print_term c s)),
- print_term (Some (Cic.Name n, Cic.Decl s)::c) t)
- | Cic.LetIn (Cic.Name n, s, t) ->
- PT.Binder (`Lambda, (PT.Ident (n,None), Some (print_term c s)),
- print_term (Some (Cic.Name n, Cic.Def (s,None))::c) t)
- | Cic.Meta _ -> PT.Implicit
- | _ as t ->
- PT.Ident ("ERROR"^CicPp.ppterm t, None)
- (*
- debug_print (lazy (CicPp.ppterm t));
- assert false
- *)
- in
- let rec print_proof context = function
- | Cic.Rel _
- | Cic.Const _ as t ->
- [GA.Executable (floc,
- GA.Tactic (floc,
- Some (GA.Apply (floc, print_term context t)), GA.Dot floc))]
- | Cic.Appl (he::tl) ->
- let tl = List.map (fun t -> t, sort_of context t) tl in
- let subgoals =
- HExtlib.filter_map (function (t,P) -> Some t | _ -> None) tl
- in
- let args =
- List.map
- (function
- | (t,P) -> Cic.Implicit None
- | (t,_) -> t)
- tl
- in
- if List.length subgoals > 1 then
- (* branch *)
- [GA.Executable (floc,
- GA.Tactic (floc,
- Some (GA.Apply (floc, print_term context (Cic.Appl (he::args)))),
- GA.Semicolon floc))] @
- [GA.Executable (floc, GA.Tactic (floc, None, GA.Branch floc))] @
- (HExtlib.list_concat
- ~sep:[GA.Executable (floc, GA.Tactic (floc, None,GA.Shift floc))]
- (List.map (print_proof context) subgoals)) @
- [GA.Executable (floc, GA.Tactic (floc, None,GA.Merge floc))]
- else
- (* simple apply *)
- [GA.Executable (floc,
- GA.Tactic (floc,
- Some (GA.Apply
- (floc, print_term context (Cic.Appl (he::args)) )), GA.Dot floc))]
- @
- (match subgoals with
- | [] -> []
- | [x] -> print_proof context x
- | _ -> assert false)
- | _ -> []
- (*
- debug_print (lazy (CicPp.ppterm t));
- assert false
- *)
- in
- let ast = print_proof context t in
- let pp t =
- (* ZACK: setting width to 80 will trigger a bug of BoxPp.render_to_string
- * which will show up using the following command line:
- * ./tptp2grafite -tptppath ~tassi/TPTP-v3.1.1 GRP170-1 *)
- let width = max_int in
- let term_pp content_term =
- let pres_term = TermContentPres.pp_ast content_term in
- let dummy_tbl = Hashtbl.create 1 in
- let markup = CicNotationPres.render dummy_tbl pres_term in
- let s = "(" ^ BoxPp.render_to_string List.hd width markup ^ ")" in
- Pcre.substitute
- ~pat:"\\\\forall [Ha-z][a-z0-9_]*" ~subst:(fun x -> "\n" ^ x) s
- in
- CicNotationPp.set_pp_term term_pp;
- let lazy_term_pp = fun x -> assert false in
- let obj_pp = CicNotationPp.pp_obj CicNotationPp.pp_term in
- GrafiteAstPp.pp_statement ~term_pp ~lazy_term_pp ~obj_pp t
- in
- String.concat "\n" (List.map pp ast)
-;;
-let auto_all tables universe cache context metasenv gl flags =
- let solutions, cache, _ =
- auto_all_solutions 0 tables universe cache context metasenv gl flags
- in
- solutions, cache
-;;
-*)
-
let auto flags metasenv tables universe cache context metasenv gl =
let initial_time = Unix.gettimeofday() in
let goals = order_new_goals metasenv [] gl CicPp.ppterm in
let goals = List.map (fun (x,s) -> D(x,flags.maxdepth,s)) goals in
- let elems = [metasenv,[],1,goals,[]] in
+ let elems = [metasenv,[],1,[],goals,[]] in
match auto_main tables 0 context flags universe cache elems with
| Proved (metasenv,subst,_, tables,cache,_) ->
debug_print(lazy
let depth = int "depth" ((AutoTypes.default_flags()).AutoTypes.maxdepth) in
let width = int "width" ((AutoTypes.default_flags()).AutoTypes.maxwidth) in
let size = int "size" ((AutoTypes.default_flags()).AutoTypes.maxsize) in
+ let gsize = int "gsize" ((AutoTypes.default_flags()).AutoTypes.maxgoalsizefactor) in
let timeout = int "timeout" 0 in
{ AutoTypes.maxdepth =
if use_only_paramod then 2 else depth;
AutoTypes.use_only_paramod = use_only_paramod;
AutoTypes.close_more = close_more;
AutoTypes.dont_cache_failures = false;
+ AutoTypes.maxgoalsizefactor = gsize;
}
let applyS_tac ~dbd ~term ~params ~universe =
ProofEngineTypes.mk_tactic
(fun status ->
try
- let _, proof, gl,_,_ =
+ let proof, gl,_,_ =
apply_smart ~dbd ~term ~subst:[] ~universe
(flags_of_params params ~for_applyS:true ()) status
in
let superposition_tac ~target ~table ~subterms_only ~demod_table status =
Saturation.reset_refs();
let proof,goalno = status in
- let curi,metasenv,pbo,pty, attrs = proof in
+ let curi,metasenv,_subst,pbo,pty, attrs = proof in
let metano,context,ty = CicUtil.lookup_meta goalno metasenv in
let eq_uri,tty = eq_and_ty_of_goal ty in
let env = (metasenv, context, CicUniv.empty_ugraph) in
proof,[goalno]
;;
-let auto_tac ~(dbd:HMysql.dbd) ~params ~universe (proof, goal) =
+let auto_tac ~(dbd:HSql.dbd) ~params ~universe (proof, goal) =
(* argument parsing *)
let string = string params in
let bool = bool params in
~target ~table ~subterms_only ~demod_table (proof,goal)
| false ->
(* this is the real auto *)
- let _,metasenv,_,_, _ = proof in
+ let _,metasenv,_subst,_,_, _ = proof in
let _,context,goalty = CicUtil.lookup_meta goal metasenv in
let flags = flags_of_params params () in
(* just for testing *)
let use_library = flags.use_library in
let tables,cache,newmeta =
- init_cache_and_tables dbd use_library flags.use_only_paramod
- universe (proof, goal) in
+ init_cache_and_tables ~dbd use_library flags.use_only_paramod true
+ false universe (proof, goal) in
let tables,cache,newmeta =
if flags.close_more then
close_more
auto_all_solutions universe cache
else tables,cache,newmeta in
let initial_time = Unix.gettimeofday() in
- let (_,oldmetasenv,_,_, _) = proof in
+ let (_,oldmetasenv,_subst,_,_, _) = proof in
hint := None;
let elem =
- metasenv,[],1,[D (goal,flags.maxdepth,P)],[]
+ metasenv,[],1,[],[D (goal,flags.maxdepth,P)],[]
in
match auto_main tables newmeta context flags universe cache [elem] with
| Proved (metasenv,subst,_, tables,cache,_) ->
prerr_endline
("TIME:"^string_of_float(Unix.gettimeofday()-.initial_time));
- (* script generation
- let irl = mk_irl context in
- let goal_term = Cic.Meta(goal, irl) in
- let proof_term = CicMetaSubst.apply_subst subst goal_term in
- HLog.debug (cic2grafite context metasenv proof_term);
- *)
- let proof,metasenv =
+ let proof,metasenv =
ProofEngineHelpers.subst_meta_and_metasenv_in_proof
- proof goal (CicMetaSubst.apply_subst subst) metasenv
+ proof goal subst metasenv
in
let opened =
ProofEngineHelpers.compare_metasenvs ~oldmetasenv
| _ -> raise (ProofEngineTypes.Fail (lazy ("The goal is not an equality ")))
;;
+(* performs steps of rewrite with the universe, obtaining if possible
+ * a trivial goal *)
+let solve_rewrite_tac ~universe ?(steps=1) (proof,goal as status)=
+ let _,metasenv,_subst,_,_,_ = proof in
+ let _,context,ty = CicUtil.lookup_meta goal metasenv in
+ let eq_uri = eq_of_goal ty in
+ let (active,passive,bag), cache, maxm =
+ (* we take the whole universe (no signature filtering) *)
+ init_cache_and_tables false true false true universe (proof,goal)
+ in
+ let initgoal = [], metasenv, ty in
+ let table =
+ let equalities = (Saturation.list_of_passive passive) in
+ (* we demodulate using both actives passives *)
+ List.fold_left (fun tbl eq -> Indexing.index tbl eq) (snd active) equalities
+ in
+ let env = metasenv,context,CicUniv.empty_ugraph in
+ match Indexing.solve_demodulating bag env table initgoal steps with
+ | Some (proof, metasenv, newty) ->
+ let refl =
+ match newty with
+ | Cic.Appl[Cic.MutInd _;eq_ty;left;_] ->
+ Equality.Exact (Equality.refl_proof eq_uri eq_ty left)
+ | _ -> assert false
+ in
+ let proofterm,_ =
+ Equality.build_goal_proof
+ bag eq_uri proof refl newty [] context metasenv
+ in
+ ProofEngineTypes.apply_tactic
+ (PrimitiveTactics.apply_tac ~term:proofterm) status
+ | None ->
+ raise
+ (ProofEngineTypes.Fail (lazy
+ ("Unable to solve with " ^ string_of_int steps ^ " demodulations")))
+;;
+let solve_rewrite_tac ~universe ?steps () =
+ ProofEngineTypes.mk_tactic (solve_rewrite_tac ~universe ?steps)
+;;
+
(* DEMODULATE *)
let demodulate_tac ~dbd ~universe (proof,goal)=
- let curi,metasenv,pbo,pty, attrs = proof in
+ let curi,metasenv,_subst,pbo,pty, attrs = proof in
let metano,context,ty = CicUtil.lookup_meta goal metasenv in
let irl = CicMkImplicit.identity_relocation_list_for_metavariable context in
- let initgoal = [], [], ty in
+ let initgoal = [], metasenv, ty in
let eq_uri = eq_of_goal ty in
let (active,passive,bag), cache, maxm =
- init_cache_and_tables dbd false true universe (proof,goal) in
+ init_cache_and_tables
+ ~dbd false true true false universe (proof,goal)
+ in
let equalities = (Saturation.list_of_passive passive) in
(* we demodulate using both actives passives *)
let table =
in
let extended_metasenv = (maxm,context,newty)::metasenv in
let extended_status =
- (curi,extended_metasenv,pbo,pty, attrs),goal in
+ (curi,extended_metasenv,_subst,pbo,pty, attrs),goal in
let (status,newgoals) =
ProofEngineTypes.apply_tactic
(PrimitiveTactics.apply_tac ~term:proofterm)
let demodulate_tac ~dbd ~universe =
ProofEngineTypes.mk_tactic (demodulate_tac ~dbd ~universe);;
+let pp_proofterm = Equality.pp_proofterm;;
+
+let revision = "$Revision$";;
+let size_and_depth context metasenv t = 100, 100