open Printf
let print ?(depth=0) s =
- prerr_endline (String.make depth '\t'^Lazy.force s)
-let noprint ?(depth=0) _ = ()
+ prerr_endline (String.make (2*depth) ' '^Lazy.force s)
+let noprint ?depth:(_=0) _ = ()
let debug_print = noprint
open Continuationals.Stack
open NTacStatus
-module Ast = CicNotationPt
+module Ast = NotationPt
(* ======================= statistics ========================= *)
module RHT = struct
type t = NReference.reference
- let equal = (==)
- let compare = Pervasives.compare
- let hash = Hashtbl.hash
+ let equal = NReference.eq
+ let compare = NReference.compare
+ let hash = NReference.hash
end;;
module RefHash = Hashtbl.Make(RHT);;
let toref f tbl t =
match t with
| Ast.NRef n ->
- f tbl n
+ f tbl n
| Ast.NCic _ (* local candidate *)
| _ -> ()
else true
with Not_found -> true
-let print_stat tbl =
+let print_stat _status tbl =
let l = RefHash.fold (fun a v l -> (a,v)::l) tbl [] in
let relevance v = float !(v.uses) /. float !(v.nominations) in
let vcompare (_,v1) (_,v2) =
Pervasives.compare (relevance v1) (relevance v2) in
let l = List.sort vcompare l in
+ let short_name r =
+ Filename.chop_extension
+ (Filename.basename (NReference.string_of_reference r))
+ in
let vstring (a,v)=
- CicNotationPp.pp_term (Ast.NCic (NCic.Const a)) ^ ": rel = " ^
+ short_name a ^ ": rel = " ^
(string_of_float (relevance v)) ^
"; uses = " ^ (string_of_int !(v.uses)) ^
"; nom = " ^ (string_of_int !(v.nominations)) in
lazy ("\n\nSTATISTICS:\n" ^
- String.concat "\n" (List.map vstring l))
+ String.concat "\n" (List.map vstring l))
(* ======================= utility functions ========================= *)
module IntSet = Set.Make(struct type t = int let compare = compare end)
let _,_,metasenv,subst,_ = status#obj in
try
let _, ctx, ty = NCicUtils.lookup_meta g metasenv in
- let ty = NCicUntrusted.apply_subst subst ctx ty in
- let ctx = NCicUntrusted.apply_subst_context
+ let ty = NCicUntrusted.apply_subst status subst ctx ty in
+ let ctx = NCicUntrusted.apply_subst_context status
~fix_projections:true subst ctx
in
NTacStatus.mk_cic_term ctx ty
let is_a_fact status ty = branch status ty = 0
let is_a_fact_obj s uri =
- let obj = NCicEnvironment.get_checked_obj uri in
+ let obj = NCicEnvironment.get_checked_obj s uri in
match obj with
| (_,_,[],[],NCic.Constant(_,_,_,ty,_)) ->
is_a_fact s (mk_cic_term [] ty)
| _ -> false
let is_a_fact_ast status subst metasenv ctx cand =
- debug_print ~depth:0
- (lazy ("------- checking " ^ CicNotationPp.pp_term cand));
- let status, t = disambiguate status ctx ("",0,cand) None in
+ noprint ~depth:0
+ (lazy ("checking facts " ^ NotationPp.pp_term status cand));
+ let status, t = disambiguate status ctx ("",0,cand) `XTNone in
let status,t = term_of_cic_term status t ctx in
- let ty = NCicTypeChecker.typeof subst metasenv ctx t in
+ let ty = NCicTypeChecker.typeof status subst metasenv ctx t in
is_a_fact status (mk_cic_term ctx ty)
let current_goal status =
let ctx = ctx_of gty in
open_goal, ctx, gty
-let height_of_ref (NReference.Ref (uri, x)) =
+let height_of_ref status (NReference.Ref (uri, x)) =
match x with
| NReference.Decl
| NReference.Ind _
| NReference.Con _
| NReference.CoFix _ ->
- let _,height,_,_,_ = NCicEnvironment.get_checked_obj uri in
+ let _,height,_,_,_ = NCicEnvironment.get_checked_obj status uri in
height
| NReference.Def h -> h
| NReference.Fix (_,_,h) -> h
;;
(*************************** height functions ********************************)
-let fast_height_of_term t =
+let fast_height_of_term status t =
let h = ref 0 in
let rec aux =
function
| NCic.Implicit _ -> assert false
| NCic.Const nref ->
(*
- prerr_endline (NCicPp.ppterm ~metasenv:[] ~subst:[]
- ~context:[] t ^ ":" ^ string_of_int (height_of_ref nref));
+ prerr_endline (status#ppterm ~metasenv:[] ~subst:[]
+ ~context:[] t ^ ":" ^ string_of_int (height_of_ref status nref));
*)
- h := max !h (height_of_ref nref)
+ h := max !h (height_of_ref status nref)
| NCic.Prod (_,t1,t2)
| NCic.Lambda (_,t1,t2) -> aux t1; aux t2
| NCic.LetIn (_,s,ty,t) -> aux s; aux ty; aux t
let ty = get_goalty status g in
let context = ctx_of ty in
let _, ty = term_of_cic_term status ty (ctx_of ty) in
- let h = ref (fast_height_of_term ty) in
+ let h = ref (fast_height_of_term status ty) in
List.iter
(function
- | _, NCic.Decl ty -> h := max !h (fast_height_of_term ty)
+ | _, NCic.Decl ty -> h := max !h (fast_height_of_term status ty)
| _, NCic.Def (bo,ty) ->
- h := max !h (fast_height_of_term ty);
- h := max !h (fast_height_of_term bo);
+ h := max !h (fast_height_of_term status ty);
+ h := max !h (fast_height_of_term status bo);
)
context;
!h
(fun open_goal ->
h := max !h (height_of_goal open_goal status))
open_goals;
- debug_print (lazy ("altezza sequente: " ^ string_of_int !h));
+ noprint (lazy ("altezza sequente: " ^ string_of_int !h));
!h
;;
*)
let n,h,metasenv,subst,o = status#obj in
let gname, ctx, gty = List.assoc goal metasenv in
- let gty = NCicUntrusted.apply_subst subst ctx gty in
+ let gty = NCicUntrusted.apply_subst status subst ctx gty in
let build_status (pt, _, metasenv, subst) =
try
- debug_print (lazy ("refining: "^(NCicPp.ppterm ctx subst metasenv pt)));
+ debug_print (lazy ("refining: "^(status#ppterm ctx subst metasenv pt)));
let stamp = Unix.gettimeofday () in
let metasenv, subst, pt, pty =
- (* NCicRefiner.typeof status
+ (* NCicRefiner.typeof status
(* (status#set_coerc_db NCicCoercion.empty_db) *)
metasenv subst ctx pt None in
- print (lazy ("refined: "^(NCicPp.ppterm ctx subst metasenv pt)));
- debug_print (lazy ("synt: "^(NCicPp.ppterm ctx subst metasenv pty)));
+ debug_print (lazy ("refined: "^(status#ppterm ctx subst metasenv pt)));
+ noprint (lazy ("synt: "^(status#ppterm ctx subst metasenv pty)));
let metasenv, subst =
NCicUnification.unify status metasenv subst ctx gty pty *)
NCicRefiner.typeof
(status#set_coerc_db NCicCoercion.empty_db)
- metasenv subst ctx pt (Some gty)
+ metasenv subst ctx pt (`XTSome gty)
in
- debug_print (lazy (Printf.sprintf "Refined in %fs"
+ noprint (lazy (Printf.sprintf "Refined in %fs"
(Unix.gettimeofday() -. stamp)));
let status = status#set_obj (n,h,metasenv,subst,o) in
let metasenv = List.filter (fun j,_ -> j <> goal) metasenv in
with
NCicRefiner.RefineFailure msg
| NCicRefiner.Uncertain msg ->
- debug_print (lazy ("WARNING: refining in fast_eq_check failed\n" ^
- snd (Lazy.force msg) ^
- "\n in the environment\n" ^
- NCicPp.ppmetasenv subst metasenv)); None
+ debug_print (lazy ("WARNING U: refining in fast_eq_check failed\n" ^
+ snd (Lazy.force msg) ^
+ "\n in the environment\n" ^
+ status#ppmetasenv subst metasenv)); None
| NCicRefiner.AssertFailure msg ->
- debug_print (lazy ("WARNING: refining in fast_eq_check failed" ^
+ debug_print (lazy ("WARNING F: refining in fast_eq_check failed" ^
Lazy.force msg ^
- "\n in the environment\n" ^
- NCicPp.ppmetasenv subst metasenv)); None
+ "\n in the environment\n" ^
+ status#ppmetasenv subst metasenv)); None
+ | Sys.Break as e -> raise e
| _ -> None
in
HExtlib.filter_map build_status
| Error _ -> debug_print (lazy ("no paramod proof found"));[]
;;
-let index_local_equations eq_cache status =
- debug_print (lazy "indexing equations");
+let index_local_equations eq_cache ?(flag=false) status =
+ if flag then
+ NCicParamod.empty_state
+ else begin
+ noprint (lazy "indexing equations");
let open_goals = head_goals status#stack in
let open_goal = List.hd open_goals in
let ngty = get_goalty status open_goal in
+ let _,_,metasenv,subst,_ = status#obj in
let ctx = apply_subst_context ~fix_projections:true status (ctx_of ngty) in
let c = ref 0 in
List.fold_left
c:= !c+1;
let t = NCic.Rel !c in
try
- let ty = NCicTypeChecker.typeof [] [] ctx t in
+ let ty = NCicTypeChecker.typeof status subst metasenv ctx t in
if is_a_fact status (mk_cic_term ctx ty) then
- (debug_print(lazy("eq indexing " ^ (NCicPp.ppterm ctx [] [] ty)));
- NCicParamod.forward_infer_step eq_cache t ty)
+ (debug_print(lazy("eq indexing " ^ (status#ppterm ctx subst metasenv ty)));
+ NCicParamod.forward_infer_step status metasenv subst ctx eq_cache t ty)
else
- (debug_print (lazy ("not a fact: " ^ (NCicPp.ppterm ctx [] [] ty)));
+ (noprint (lazy ("not a fact: " ^ (status#ppterm ctx subst metasenv ty)));
eq_cache)
with
| NCicTypeChecker.TypeCheckerFailure _
| NCicTypeChecker.AssertFailure _ -> eq_cache)
eq_cache ctx
+ end
;;
-let fast_eq_check_tac ~params s =
+let index_local_equations2 eq_cache status open_goal lemmas ?flag:(_=false) nohyps =
+ noprint (lazy "indexing equations");
+ let eq_cache,lemmas =
+ match lemmas with
+ None -> eq_cache,[]
+ | Some l -> NCicParamod.empty_state,l
+ in
+ let ngty = get_goalty status open_goal in
+ let _,_,metasenv,subst,_ = status#obj in
+ let ctx = apply_subst_context ~fix_projections:true status (ctx_of ngty) in
+ let status,lemmas =
+ List.fold_left
+ (fun (status,lemmas) l ->
+ let status,l = NTacStatus.disambiguate status ctx l `XTNone in
+ let status,l = NTacStatus.term_of_cic_term status l ctx in
+ status,l::lemmas)
+ (status,[]) lemmas in
+ let local_equations =
+ if nohyps then [] else
+ List.map (fun i -> NCic.Rel (i + 1))
+ (HExtlib.list_seq 1 (List.length ctx)) in
+ let lemmas = lemmas @ local_equations in
+ List.fold_left
+ (fun eq_cache t ->
+ try
+ let ty = NCicTypeChecker.typeof status subst metasenv ctx t in
+ if is_a_fact status (mk_cic_term ctx ty) then
+ (debug_print(lazy("eq indexing " ^ (status#ppterm ctx subst metasenv ty)));
+ NCicParamod.forward_infer_step status metasenv subst ctx eq_cache t ty)
+ else
+ (noprint (lazy ("not a fact: " ^ (status#ppterm ctx subst metasenv ty)));
+ eq_cache)
+ with
+ | NCicTypeChecker.TypeCheckerFailure _
+ | NCicTypeChecker.AssertFailure _ -> eq_cache)
+ eq_cache lemmas
+;;
+
+let fast_eq_check_tac ~params:_ s =
let unit_eq = index_local_equations s#eq_cache s in
dist_fast_eq_check unit_eq s
;;
| s::_ -> s
;;
-let paramod_tac ~params s =
+let paramod_tac ~params:_ s =
let unit_eq = index_local_equations s#eq_cache s in
NTactics.distribute_tac (paramod unit_eq) s
;;
;;
let demod_tac ~params s =
- let unit_eq = index_local_equations s#eq_cache s in
- NTactics.distribute_tac (demod unit_eq) s
+ let unit_eq s i =
+ index_local_equations2 s#eq_cache s i (fst params)
+ (List.mem_assoc "nohyps" (snd params))
+ in
+ NTactics.distribute_tac (fun s i -> demod (unit_eq s i) s i) s
;;
(*
(*************** subsumption ****************)
-let close_wrt_context =
+let close_wrt_context status =
List.fold_left
(fun ty ctx_entry ->
match ctx_entry with
| name, NCic.Decl t -> NCic.Prod(name,t,ty)
- | name, NCic.Def(bo, _) -> NCicSubstitution.subst bo ty)
+ | _name, NCic.Def(bo, _) -> NCicSubstitution.subst status bo ty)
;;
let args_for_context ?(k=1) ctx =
List.fold_left
(fun (n,l) ctx_entry ->
match ctx_entry with
- | name, NCic.Decl t -> n+1,NCic.Rel(n)::l
- | name, NCic.Def(bo, _) -> n+1,l)
+ | _name, NCic.Decl _t -> n+1,NCic.Rel(n)::l
+ | _name, NCic.Def(_bo, _) -> n+1,l)
(k,[]) ctx in
args
-let constant_for_meta ctx ty i =
+let constant_for_meta status ctx ty i =
let name = "cic:/foo"^(string_of_int i)^".con" in
let uri = NUri.uri_of_string name in
- let ty = close_wrt_context ty ctx in
- (* prerr_endline (NCicPp.ppterm [] [] [] ty); *)
+ let ty = close_wrt_context status ty ctx in
+ (* prerr_endline (status#ppterm [] [] [] ty); *)
let attr = (`Generated,`Definition,`Local) in
let obj = NCic.Constant([],name,None,ty,attr) in
(* Constant of relevance * string * term option * term * c_attr *)
List.fold_left
(fun (metasenv,subst) (i,(iattr,ctx,ty)) ->
let ikind = NCicUntrusted.kind_of_meta iattr in
- let metasenv,j,instance,ty =
+ let metasenv,_j,instance,ty =
NCicMetaSubst.mk_meta ~attrs:iattr
metasenv ctx ~with_type:ty ikind in
let s_entry = i,(iattr, ctx, instance, ty) in
(* close metasenv returns a ground instance of all the metas in the
metasenv, insantiatied with axioms, and the list of these axioms *)
-let close_metasenv metasenv subst =
+let close_metasenv status metasenv subst =
(*
let metasenv = NCicUntrusted.apply_subst_metasenv subst metasenv in
*)
- let metasenv = NCicUntrusted.sort_metasenv subst metasenv in
+ let metasenv = NCicUntrusted.sort_metasenv status subst metasenv in
List.fold_left
- (fun (subst,objs) (i,(iattr,ctx,ty)) ->
- let ty = NCicUntrusted.apply_subst subst ctx ty in
+ (fun (subst,objs) (i,(_iattr,ctx,ty)) ->
+ let ty = NCicUntrusted.apply_subst status subst ctx ty in
let ctx =
- NCicUntrusted.apply_subst_context ~fix_projections:true
+ NCicUntrusted.apply_subst_context status ~fix_projections:true
subst ctx in
- let (uri,_,_,_,obj) as okind =
- constant_for_meta ctx ty i in
+ let (uri,_,_,_,_obj) as okind =
+ constant_for_meta status ctx ty i in
try
- NCicEnvironment.check_and_add_obj okind;
+ NCicEnvironment.check_and_add_obj status okind;
let iref = NReference.reference_of_spec uri NReference.Decl in
let iterm =
let args = args_for_context ctx in
if args = [] then NCic.Const iref
else NCic.Appl(NCic.Const iref::args)
in
- (* prerr_endline (NCicPp.ppterm ctx [] [] iterm); *)
+ (* prerr_endline (status#ppterm ctx [] [] iterm); *)
let s_entry = i, ([], ctx, iterm, ty)
in s_entry::subst,okind::objs
- with _ -> assert false)
+ with
+ Sys.Break as e -> raise e
+ | _ -> assert false)
(subst,[]) metasenv
;;
(*
let submenv = metasenv in
*)
- let subst, objs = close_metasenv submenv subst in
+ let subst, objs = close_metasenv status submenv subst in
try
List.iter
(fun i ->
let (_, ctx, t, _) = List.assoc i subst in
- debug_print (lazy (NCicPp.ppterm ctx [] [] t));
+ noprint (lazy (status#ppterm ctx [] [] t));
List.iter
(fun (uri,_,_,_,_) as obj ->
NCicEnvironment.invalidate_item (`Obj (uri, obj)))
(* (ctx,t) *)
;;
-let replace_meta i args target =
+let replace_meta status i args target =
let rec aux k = function
(* TODO: local context *)
| NCic.Meta (j,lc) when i = j ->
(match args with
| [] -> NCic.Rel 1
| _ -> let args =
- List.map (NCicSubstitution.subst_meta lc) args in
+ List.map (NCicSubstitution.subst_meta status lc) args in
NCic.Appl(NCic.Rel k::args))
- | NCic.Meta (j,lc) as m ->
+ | NCic.Meta (_j,lc) as m ->
(match lc with
_,NCic.Irl _ -> m
| n,NCic.Ctx l ->
NCic.Meta
(i,(0,NCic.Ctx
(List.map (fun t ->
- aux k (NCicSubstitution.lift n t)) l))))
- | t -> NCicUtils.map (fun _ k -> k+1) k aux t
+ aux k (NCicSubstitution.lift status n t)) l))))
+ | t -> NCicUtils.map status (fun _ k -> k+1) k aux t
in
aux 1 target
;;
-let close_wrt_metasenv subst =
+let close_wrt_metasenv status subst =
List.fold_left
- (fun ty (i,(iattr,ctx,mty)) ->
- let mty = NCicUntrusted.apply_subst subst ctx mty in
+ (fun ty (i,(_iattr,ctx,mty)) ->
+ let mty = NCicUntrusted.apply_subst status subst ctx mty in
let ctx =
- NCicUntrusted.apply_subst_context ~fix_projections:true
+ NCicUntrusted.apply_subst_context status ~fix_projections:true
subst ctx in
- let cty = close_wrt_context mty ctx in
+ let cty = close_wrt_context status mty ctx in
let name = "foo"^(string_of_int i) in
- let ty = NCicSubstitution.lift 1 ty in
+ let ty = NCicSubstitution.lift status 1 ty in
let args = args_for_context ~k:1 ctx in
- (* prerr_endline (NCicPp.ppterm ctx [] [] iterm); *)
- let ty = replace_meta i args ty
+ (* prerr_endline (status#ppterm ctx [] [] iterm); *)
+ let ty = replace_meta status i args ty
in
NCic.Prod(name,cty,ty))
;;
let subset = IntSet.remove g subset in
let elems = IntSet.elements subset in
let _, ctx, ty = NCicUtils.lookup_meta g metasenv in
- let ty = NCicUntrusted.apply_subst subst ctx ty in
- debug_print (lazy ("metas in " ^ (NCicPp.ppterm ctx [] metasenv ty)));
- debug_print (lazy (String.concat ", " (List.map string_of_int elems)));
+ let ty = NCicUntrusted.apply_subst status subst ctx ty in
+ noprint (lazy ("metas in " ^ (status#ppterm ctx [] metasenv ty)));
+ noprint (lazy (String.concat ", " (List.map string_of_int elems)));
let submenv = List.filter (fun (x,_) -> IntSet.mem x subset) metasenv in
- let submenv = List.rev (NCicUntrusted.sort_metasenv subst submenv) in
+ let submenv = List.rev (NCicUntrusted.sort_metasenv status subst submenv) in
(*
let submenv = metasenv in
*)
- let ty = close_wrt_metasenv subst ty submenv in
- debug_print (lazy (NCicPp.ppterm ctx [] [] ty));
+ let ty = close_wrt_metasenv status subst ty submenv in
+ noprint (lazy (status#ppterm ctx [] [] ty));
ctx,ty
;;
(****************** smart application ********************)
-let saturate_to_ref metasenv subst ctx nref ty =
- let height = height_of_ref nref in
+let saturate_to_ref status metasenv subst ctx nref ty =
+ let height = height_of_ref status nref in
let rec aux metasenv ty args =
let ty,metasenv,moreargs =
- NCicMetaSubst.saturate ~delta:height metasenv subst ctx ty 0 in
+ NCicMetaSubst.saturate status ~delta:height metasenv subst ctx ty 0 in
match ty with
| NCic.Const(NReference.Ref (_,NReference.Def _) as nre)
- when nre<>nref ->
- let _, _, bo, _, _, _ = NCicEnvironment.get_checked_def nre in
- aux metasenv bo (args@moreargs)
+ when nre<>nref ->
+ let _, _, bo, _, _, _ = NCicEnvironment.get_checked_def status nre in
+ aux metasenv bo (args@moreargs)
| NCic.Appl(NCic.Const(NReference.Ref (_,NReference.Def _) as nre)::tl)
- when nre<>nref ->
- let _, _, bo, _, _, _ = NCicEnvironment.get_checked_def nre in
- aux metasenv (NCic.Appl(bo::tl)) (args@moreargs)
+ when nre<>nref ->
+ let _, _, bo, _, _, _ = NCicEnvironment.get_checked_def status nre in
+ aux metasenv (NCic.Appl(bo::tl)) (args@moreargs)
| _ -> ty,metasenv,(args@moreargs)
in
aux metasenv ty []
let smart_apply t unit_eq status g =
- let n,h,metasenv,subst,o = status#obj in
- let gname, ctx, gty = List.assoc g metasenv in
+ let n,h,metasenv,_subst,o = status#obj in
+ let _gname, ctx, gty = List.assoc g metasenv in
(* let ggty = mk_cic_term context gty in *)
- let status, t = disambiguate status ctx t None in
+ let status, t = disambiguate status ctx t `XTNone in
let status,t = term_of_cic_term status t ctx in
let _,_,metasenv,subst,_ = status#obj in
- let ty = NCicTypeChecker.typeof subst metasenv ctx t in
+ let ty = NCicTypeChecker.typeof status subst metasenv ctx t in
let ty,metasenv,args =
match gty with
| NCic.Const(nref)
| NCic.Appl(NCic.Const(nref)::_) ->
- saturate_to_ref metasenv subst ctx nref ty
+ saturate_to_ref status metasenv subst ctx nref ty
| _ ->
- NCicMetaSubst.saturate metasenv subst ctx ty 0 in
+ NCicMetaSubst.saturate status metasenv subst ctx ty 0 in
let metasenv,j,inst,_ = NCicMetaSubst.mk_meta metasenv ctx `IsTerm in
let status = status#set_obj (n,h,metasenv,subst,o) in
let pterm = if args=[] then t else
| NCic.Appl l -> NCic.Appl(l@args)
| _ -> NCic.Appl(t::args)
in
- noprint(lazy("pterm " ^ (NCicPp.ppterm ctx [] [] pterm)));
- noprint(lazy("pty " ^ (NCicPp.ppterm ctx [] [] ty)));
+ noprint(lazy("pterm " ^ (status#ppterm ctx [] [] pterm)));
+ noprint(lazy("pty " ^ (status#ppterm ctx [] [] ty)));
let eq_coerc =
let uri =
- NUri.uri_of_string "cic:/matita/ng/Plogic/equality/eq_coerc.con" in
+ NUri.uri_of_string "cic:/matita/basics/logic/eq_coerc.con" in
let ref = NReference.reference_of_spec uri (NReference.Def(2)) in
NCic.Const ref
in
let status = instantiate status g smart in
let _,_,metasenv,subst,_ = status#obj in
let _,ctx,jty = List.assoc j metasenv in
- let jty = NCicUntrusted.apply_subst subst ctx jty in
- debug_print(lazy("goal " ^ (NCicPp.ppterm ctx [] [] jty)));
- fast_eq_check unit_eq status j
+ let jty = NCicUntrusted.apply_subst status subst ctx jty in
+ debug_print(lazy("goal " ^ (status#ppterm ctx [] [] jty)));
+ let res = fast_eq_check unit_eq status j in
+ debug_print(lazy("ritorno da fast_eq_check"));
+ res
with
- | NCicEnvironment.ObjectNotFound s as e ->
+ | NCicEnvironment.ObjectNotFound _s as e ->
raise (Error (lazy "eq_coerc non yet defined",Some e))
| Error _ as e -> debug_print (lazy "error"); raise e
+(* FG: for now we catch TypeCheckerFailure; to be understood *)
+ | NCicTypeChecker.TypeCheckerFailure _ ->
+ debug_print (lazy "TypeCheckerFailure");
+ raise (Error (lazy "no proof found",None))
+;;
+
+let compare_statuses ~past ~present =
+ let _,_,past,_,_ = past#obj in
+ let _,_,present,_,_ = present#obj in
+ List.map fst (List.filter (fun (i,_) -> not(List.mem_assoc i past)) present),
+ List.map fst (List.filter (fun (i,_) -> not (List.mem_assoc i present)) past)
+;;
+
+(* paramodulation has only an implicit knoweledge of the symmetry of equality;
+ hence it is in trouble in proving (a = b) = (b = a) *)
+let try_sym tac status g =
+ let sym_eq = Ast.Appl [Ast.Ident("sym_eq",None); Ast.Implicit `Vector] in
+ let _,_,metasenv,subst,_ = status#obj in
+ let _, context, gty = List.assoc g metasenv in
+ let is_eq =
+ NCicParamod.is_equation status metasenv subst context gty
+ in
+ if is_eq then
+ try tac status g
+ with Error _ ->
+ let new_status = instantiate_with_ast status g ("",0,sym_eq) in
+ let go, _ = compare_statuses ~past:status ~present:new_status in
+ assert (List.length go = 1);
+ let ng = List.hd go in
+ tac new_status ng
+ else tac status g
+;;
let smart_apply_tac t s =
let unit_eq = index_local_equations s#eq_cache s in
- NTactics.distribute_tac (smart_apply t unit_eq) s
+ NTactics.distribute_tac (try_sym (smart_apply t unit_eq)) s
+ (* NTactics.distribute_tac (smart_apply t unit_eq) s *)
let smart_apply_auto t eq_cache =
- NTactics.distribute_tac (smart_apply t eq_cache)
+ NTactics.distribute_tac (try_sym (smart_apply t eq_cache))
+ (* NTactics.distribute_tac (smart_apply t eq_cache) *)
(****************** types **************)
;;
(* all_keys_of_cic_type: term -> term set *)
-let all_keys_of_cic_type metasenv subst context ty =
+let all_keys_of_cic_type status metasenv subst context ty =
let saturate ty =
(* Here we are dropping the metasenv, but this should not raise any
exception (hopefully...) *)
let ty,_,hyps =
- NCicMetaSubst.saturate ~delta:max_int metasenv subst context ty 0
+ NCicMetaSubst.saturate status ~delta:max_int metasenv subst context ty 0
in
ty,List.length hyps
in
NCic.Appl (he::tl) ->
let tl' =
List.map (fun ty ->
- let wty = NCicReduction.whd ~delta:0 ~subst context ty in
+ let wty = NCicReduction.whd status ~delta:0 ~subst context ty in
if ty = wty then
NDiscriminationTree.TermSet.add ty (aux ty)
else
| _ -> NDiscriminationTree.TermSet.empty
in
let ty,ity = saturate ty in
- let wty,iwty = saturate (NCicReduction.whd ~delta:0 ~subst context ty) in
+ let wty,iwty = saturate (NCicReduction.whd status ~delta:0 ~subst context ty) in
if ty = wty then
[ity, NDiscriminationTree.TermSet.add ty (aux ty)]
else
let context = ctx_of t in
let status, t = apply_subst status context t in
let keys =
- all_keys_of_cic_type metasenv subst context
+ all_keys_of_cic_type status metasenv subst context
(snd (term_of_cic_term status t context))
in
status,
(fun (status, acc) g ->
let gty = get_goalty status g in
let ctx = ctx_of gty in
- debug_print(lazy("th cache for: "^ppterm status gty));
- debug_print(lazy("th cache in: "^ppcontext status ctx));
+ noprint(lazy("th cache for: "^ppterm status gty));
+ noprint(lazy("th cache in: "^ppcontext status ctx));
if List.mem_assq ctx acc then status, acc else
let idx = InvRelDiscriminationTree.empty in
let status,_,idx =
(fun (status, i, idx) _ ->
let t = mk_cic_term ctx (NCic.Rel i) in
let status, keys = keys_of_term status t in
- debug_print(lazy("indexing: "^ppterm status t ^ ": " ^ string_of_int (List.length keys)));
+ noprint(lazy("indexing: "^ppterm status t ^ ": " ^ string_of_int (List.length keys)));
let idx =
List.fold_left (fun idx k ->
InvRelDiscriminationTree.index idx k t) idx keys
(status,[]) gl
;;
+let all_elements ctx cache =
+ let dummy = mk_cic_term ctx (NCic.Meta (0,(0, (NCic.Irl 0)))) in
+ try
+ let idx = List.assq ctx cache in
+ Ncic_termSet.elements
+ (InvRelDiscriminationTree.retrieve_unifiables idx dummy)
+ with Not_found -> []
+
let add_to_th t c ty =
let key_c = ctx_of t in
if not (List.mem_assq key_c c) then
let pp_idx status idx =
InvRelDiscriminationTree.iter idx
(fun k set ->
- debug_print(lazy("K: " ^ NCicInverseRelIndexable.string_of_path k));
+ noprint(lazy("K: " ^ NCicInverseRelIndexable.string_of_path k));
Ncic_termSet.iter
(fun t -> debug_print(lazy("\t"^ppterm status t)))
set)
;;
-let pp_th status =
+let pp_th (status: #NTacStatus.pstatus) =
List.iter
(fun ctx, idx ->
- debug_print(lazy( "-----------------------------------------------"));
- debug_print(lazy( (NCicPp.ppcontext ~metasenv:[] ~subst:[] ctx)));
- debug_print(lazy( "||====> "));
+ noprint(lazy( "-----------------------------------------------"));
+ noprint(lazy( (status#ppcontext ~metasenv:[] ~subst:[] ctx)));
+ noprint(lazy( "||====> "));
pp_idx status idx)
;;
do_types : bool; (* solve goals in Type *)
last : bool; (* last goal: take first solution only *)
candidates: Ast.term list option;
+ local_candidates: bool;
maxwidth : int;
maxsize : int;
maxdepth : int;
- timeout : float;
}
type cache =
{facts : th_cache; (* positive results *)
under_inspection : cic_term list * th_cache; (* to prune looping *)
+ failures : th_cache; (* to avoid repetitions *)
unit_eq : NCicParamod.state;
trace: Ast.term list
}
-let add_to_trace ~depth cache t =
+let add_to_trace status ~depth cache t =
match t with
| Ast.NRef _ ->
- debug_print ~depth (lazy ("Adding to trace: " ^ CicNotationPp.pp_term t));
- {cache with trace = t::cache.trace}
+ debug_print ~depth (lazy ("Adding to trace: " ^ NotationPp.pp_term status t));
+ {cache with trace = t::cache.trace}
| Ast.NCic _ (* local candidate *)
| _ -> (*not an application *) cache
-let pptrace tr =
+let pptrace status tr =
(lazy ("Proof Trace: " ^ (String.concat ";"
- (List.map CicNotationPp.pp_term tr))))
+ (List.map (NotationPp.pp_term status) tr))))
(* not used
let remove_from_trace cache t =
match t with
| Ast.NRef _ ->
- (match cache.trace with
- | _::tl -> {cache with trace = tl}
+ (match cache.trace with
+ | _::tl -> {cache with trace = tl}
| _ -> assert false)
| Ast.NCic _ (* local candidate *)
| _ -> (*not an application *) cache *)
type fail = goal * cic_term
type candidate = int * Ast.term (* unique candidate number, candidate *)
-exception Gaveup of IntSet.t (* a sublist of unprovable conjunctive
- atoms of the input goals *)
+exception Gaveup of th_cache (* failure cache *)
exception Proved of NTacStatus.tac_status * Ast.term list
(* let close_failures _ c = c;; *)
(* let add_to_cache_and_del_from_orlist_if_green_cut _ _ c _ _ o f _ = c, o, f, false ;; *)
(* let cache_add_underinspection c _ _ = c;; *)
-let init_cache ?(facts=[]) ?(under_inspection=[],[])
+let init_cache ?(facts=[]) ?(under_inspection=[],[])
+ ?(failures=[])
?(unit_eq=NCicParamod.empty_state)
?(trace=[])
_ =
{facts = facts;
+ failures = failures;
under_inspection = under_inspection;
unit_eq = unit_eq;
trace = trace}
-let only signature _context candidate = true
+let only _signature _context _candidate = true
(*
(* TASSI: nel trie ci mettiamo solo il body, non il ty *)
let candidate_ty =
NCicTypeChecker.typeof ~subst:[] ~metasenv:[] [] candidate
in
- let height = fast_height_of_term candidate_ty in
+ let height = fast_height_of_term status candidate_ty in
let rc = signature >= height in
if rc = false then
- debug_print (lazy ("Filtro: " ^ NCicPp.ppterm ~context:[] ~subst:[]
+ noprint (lazy ("Filtro: " ^ status#ppterm ~context:[] ~subst:[]
~metasenv:[] candidate ^ ": " ^ string_of_int height))
else
- debug_print (lazy ("Tengo: " ^ NCicPp.ppterm ~context:[] ~subst:[]
+ noprint (lazy ("Tengo: " ^ status#ppterm ~context:[] ~subst:[]
~metasenv:[] candidate ^ ": " ^ string_of_int height));
rc *)
let sort_candidates status ctx candidates =
let _,_,metasenv,subst,_ = status#obj in
let branch cand =
- let status,ct = disambiguate status ctx ("",0,cand) None in
+ let status,ct = disambiguate status ctx ("",0,cand) `XTNone in
let status,t = term_of_cic_term status ct ctx in
- let ty = NCicTypeChecker.typeof subst metasenv ctx t in
+ let ty = NCicTypeChecker.typeof status subst metasenv ctx t in
let res = branch status (mk_cic_term ctx ty) in
- debug_print (lazy ("branch factor for: " ^ (ppterm status ct) ^ " = "
- ^ (string_of_int res)));
+ noprint (lazy ("branch factor for: " ^ (ppterm status ct) ^ " = "
+ ^ (string_of_int res)));
res
in
let candidates = List.map (fun t -> branch t,t) candidates in
let candidates =
List.sort (fun (a,_) (b,_) -> a - b) candidates in
let candidates = List.map snd candidates in
- debug_print (lazy ("candidates =\n" ^ (String.concat "\n"
- (List.map CicNotationPp.pp_term candidates))));
+ noprint (lazy ("candidates =\n" ^ (String.concat "\n"
+ (List.map (NotationPp.pp_term status) candidates))));
candidates
let sort_new_elems l =
List.sort (fun (_,s1) (_,s2) -> openg_no s1 - openg_no s2) l
-let try_candidate ?(smart=0) flags depth status eq_cache ctx t =
- try
- debug_print ~depth (lazy ("try " ^ CicNotationPp.pp_term t));
- let status =
- if smart= 0 then NTactics.apply_tac ("",0,t) status
- else if smart = 1 then smart_apply_auto ("",0,t) eq_cache status
- else (* smart = 2: both *)
- try NTactics.apply_tac ("",0,t) status
- with Error _ ->
+let rec stack_goals level gs =
+ if level = 0 then []
+ else match gs with
+ | [] -> assert false
+ | (g,_,_,_,_)::s ->
+ let is_open = function
+ | (_,Continuationals.Stack.Open i) -> Some i
+ | (_,Continuationals.Stack.Closed _) -> None
+ in
+ HExtlib.filter_map is_open g @ stack_goals (level-1) s
+;;
+
+let open_goals level status = stack_goals level status#stack
+;;
+
+let try_candidate ?(smart=0) _flags depth status eq_cache _ctx t =
+ try
+ (*let old_og_no = List.length (open_goals (depth+1) status) in*)
+ debug_print ~depth (lazy ("try " ^ (string_of_int smart) ^ " : "
+ ^ (NotationPp.pp_term status) t));
+ let status =
+ if smart = 0 then NTactics.apply_tac ("",0,t) status
+ else if smart = 1 then
smart_apply_auto ("",0,t) eq_cache status
- in
-(*
- let og_no = openg_no status in
- if (* og_no > flags.maxwidth || *)
- ((depth + 1) = flags.maxdepth && og_no <> 0) then
- (debug_print ~depth (lazy "pruned immediately"); None)
- else *)
- (* useless
- let status, cict = disambiguate status ctx ("",0,t) None in
- let status,ct = term_of_cic_term status cict ctx in
- let _,_,metasenv,subst,_ = status#obj in
- let ty = NCicTypeChecker.typeof subst metasenv ctx ct in
- let res = branch status (mk_cic_term ctx ty) in
- if smart=1 && og_no > res then
- (print (lazy ("branch factor for: " ^ (ppterm status cict) ^ " = "
- ^ (string_of_int res) ^ " vs. " ^ (string_of_int og_no)));
- print ~depth (lazy "strange application"); None)
- else *)
- (incr candidate_no;
- Some ((!candidate_no,t),status))
- with Error (msg,exn) -> debug_print ~depth (lazy "failed"); None
-;;
-
-let sort_of subst metasenv ctx t =
- let ty = NCicTypeChecker.typeof subst metasenv ctx t in
- let metasenv',ty = NCicUnification.fix_sorts metasenv subst ty in
+ else (* smart = 2: both *)
+ try NTactics.apply_tac ("",0,t) status
+ with Error _ ->
+ smart_apply_auto ("",0,t) eq_cache status
+ in
+(* FG: this optimization rules out some applications of
+ * lift_bind (from contribs/lambda_delta/Basic_2/substitution/lift.ma)
+ *
+ (* we compare the expected branching with the actual one and
+ prune the candidate when the latter is larger. The optimization
+ is meant to rule out stange applications of flexible terms,
+ such as the application of eq_f that always succeeds.
+ There is some gain but less than expected *)
+ let og_no = List.length (open_goals (depth+1) status) in
+ let status, cict = disambiguate status ctx ("",0,t) None in
+ let status,ct = term_of_cic_term status cict ctx in
+ let _,_,metasenv,subst,_ = status#obj in
+ let ty = NCicTypeChecker.typeof status subst metasenv ctx ct in
+ let res = branch status (mk_cic_term ctx ty) in
+ let diff = og_no - old_og_no in
+ debug_print (lazy ("expected branching: " ^ (string_of_int res)));
+ debug_print (lazy ("actual: branching" ^ (string_of_int diff)));
+ (* some flexibility *)
+ if og_no - old_og_no > res then
+ (debug_print (lazy ("branch factor for: " ^ (ppterm status cict) ^ " = "
+ ^ (string_of_int res) ^ " vs. " ^ (string_of_int og_no)));
+ debug_print ~depth (lazy "strange application"); None)
+ else
+*) (incr candidate_no; Some ((!candidate_no,t),status))
+ with Error _ -> debug_print ~depth (lazy "failed"); None
+;;
+
+let sort_of status subst metasenv ctx t =
+ let ty = NCicTypeChecker.typeof status subst metasenv ctx t in
+ let metasenv',ty = NCicUnification.fix_sorts status metasenv subst ty in
assert (metasenv = metasenv');
- NCicTypeChecker.typeof subst metasenv ctx ty
+ NCicTypeChecker.typeof status subst metasenv ctx ty
;;
let type0= NUri.uri_of_string ("cic:/matita/pts/Type0.univ")
;;
-let perforate_small subst metasenv context t =
+let perforate_small status subst metasenv context t =
let rec aux = function
| NCic.Appl (hd::tl) ->
- let map t =
- let s = sort_of subst metasenv context t in
- match s with
- | NCic.Sort(NCic.Type [`Type,u])
- when u=type0 -> NCic.Meta (0,(0,NCic.Irl 0))
- | _ -> aux t
- in
- NCic.Appl (hd::List.map map tl)
+ let map t =
+ let s = sort_of status subst metasenv context t in
+ match s with
+ | NCic.Sort(NCic.Type [`Type,u])
+ when u=type0 -> NCic.Meta (0,(0,NCic.Irl 0))
+ | _ -> aux t
+ in
+ NCic.Appl (hd::List.map map tl)
| t -> t
in
aux t
cands, diff more_cands cands
;;
-let get_candidates ?(smart=true) depth flags status cache signature gty =
- let maxd = ((depth + 1) = flags.maxdepth) in
+let is_a_needed_uri s =
+ s = "cic:/matita/basics/logic/eq.ind" ||
+ s = "cic:/matita/basics/logic/sym_eq.con" ||
+ s = "cic:/matita/basics/logic/trans_eq.con" ||
+ s = "cic:/matita/basics/logic/eq_f3.con" ||
+ s = "cic:/matita/basics/logic/eq_f2.con" ||
+ s = "cic:/matita/basics/logic/eq_f.con"
+
+let get_candidates ?(smart=true) ~pfailed depth flags status cache _signature gty =
let universe = status#auto_cache in
let _,_,metasenv,subst,_ = status#obj in
let context = ctx_of gty in
let _, raw_gty = term_of_cic_term status gty context in
+ let is_prod, _is_eq =
+ let status, t = term_of_cic_term status gty context in
+ let t = NCicReduction.whd status subst context t in
+ match t with
+ | NCic.Prod _ -> true, false
+ | _ -> false, NCicParamod.is_equation status metasenv subst context t
+ in
+ debug_print ~depth (lazy ("gty:" ^ NTacStatus.ppterm status gty));
+ let is_eq =
+ NCicParamod.is_equation status metasenv subst context raw_gty
+ in
let raw_weak_gty, weak_gty =
if smart then
match raw_gty with
- | NCic.Appl _
- | NCic.Const _
- | NCic.Rel _ ->
- let weak = perforate_small subst metasenv context raw_gty in
- Some weak, Some (mk_cic_term context weak)
- | _ -> None,None
+ | NCic.Appl _
+ | NCic.Const _
+ | NCic.Rel _ ->
+ let raw_weak =
+ perforate_small status subst metasenv context raw_gty in
+ let weak = mk_cic_term context raw_weak in
+ noprint ~depth (lazy ("weak_gty:" ^ NTacStatus.ppterm status weak));
+ Some raw_weak, Some (weak)
+ | _ -> None,None
else None,None
in
+ (* we now compute global candidates *)
let global_cands, smart_global_cands =
- match flags.candidates with
- | Some l when (not maxd) -> l,[]
- | Some _
- | None ->
- let mapf s =
- let to_ast = function
- | NCic.Const r when true (*is_relevant statistics r*) -> Some (Ast.NRef r)
- | NCic.Const _ -> None
- | _ -> assert false in
- HExtlib.filter_map
- to_ast (NDiscriminationTree.TermSet.elements s) in
- let g,l =
- get_cands
- (NDiscriminationTree.DiscriminationTree.retrieve_unifiables
- universe)
- NDiscriminationTree.TermSet.diff
- NDiscriminationTree.TermSet.empty
- raw_gty raw_weak_gty in
- mapf g, mapf l in
+ let mapf s =
+ let to_ast = function
+ | NCic.Const r when true
+ (*is_relevant statistics r*) -> Some (Ast.NRef r)
+ (* | NCic.Const _ -> None *)
+ | _ -> assert false in
+ HExtlib.filter_map
+ to_ast (NDiscriminationTree.TermSet.elements s) in
+ let g,l =
+ get_cands
+ (NDiscriminationTree.DiscriminationTree.retrieve_unifiables universe)
+ NDiscriminationTree.TermSet.diff
+ NDiscriminationTree.TermSet.empty
+ raw_gty raw_weak_gty in
+ mapf g, mapf l
+ in
+ let global_cands,smart_global_cands =
+ if flags.local_candidates then global_cands,smart_global_cands
+ else let filter = List.filter (function Ast.NRef NReference.Ref (uri,_) -> is_a_needed_uri
+ (NUri.string_of_uri
+ uri) | _ -> false)
+ in filter global_cands,filter smart_global_cands
+ in
+ (* we now compute local candidates *)
let local_cands,smart_local_cands =
let mapf s =
let to_ast t =
- let _status, t = term_of_cic_term status t context
- in Ast.NCic t in
- List.map to_ast (Ncic_termSet.elements s) in
+ let _status, t = term_of_cic_term status t context
+ in Ast.NCic t in
+ List.map to_ast (Ncic_termSet.elements s) in
let g,l =
get_cands
- (fun ty -> search_in_th ty cache)
- Ncic_termSet.diff Ncic_termSet.empty gty weak_gty in
- mapf g, mapf l in
- sort_candidates status context (global_cands@local_cands),
- sort_candidates status context (smart_global_cands@smart_local_cands)
-;;
-
-(* old version
-let get_candidates ?(smart=true) status cache signature gty =
- let universe = status#auto_cache in
- let _,_,metasenv,subst,_ = status#obj in
- let context = ctx_of gty in
- let t_ast t =
- let _status, t = term_of_cic_term status t context
- in Ast.NCic t in
- let c_ast = function
- | NCic.Const r -> Ast.NRef r | _ -> assert false in
- let _, raw_gty = term_of_cic_term status gty context in
- let keys = all_keys_of_cic_term metasenv subst context raw_gty in
- (* we only keep those keys that do not require any intros for now *)
- let no_intros_keys = snd (List.hd keys) in
- let cands =
- NDiscriminationTree.TermSet.fold
- (fun ty acc ->
- NDiscriminationTree.TermSet.union acc
- (NDiscriminationTree.DiscriminationTree.retrieve_unifiables
- universe ty)
- ) no_intros_keys NDiscriminationTree.TermSet.empty in
-(* old code:
- let cands = NDiscriminationTree.DiscriminationTree.retrieve_unifiables
- universe raw_gty in
-*)
- let local_cands =
- NDiscriminationTree.TermSet.fold
- (fun ty acc ->
- Ncic_termSet.union acc (search_in_th (mk_cic_term context ty) cache)
- ) no_intros_keys Ncic_termSet.empty in
-(* old code:
- let local_cands = search_in_th gty cache in
-*)
- debug_print (lazy ("candidates for" ^ NTacStatus.ppterm status gty));
- debug_print (lazy ("local cands = " ^ (string_of_int (List.length (Ncic_termSet.elements local_cands)))));
- let together global local =
- List.map c_ast
- (List.filter (only signature context)
- (NDiscriminationTree.TermSet.elements global)) @
- List.map t_ast (Ncic_termSet.elements local) in
- let candidates = together cands local_cands in
- let candidates = sort_candidates status context candidates in
- let smart_candidates =
- if smart then
- match raw_gty with
- | NCic.Appl _
- | NCic.Const _
- | NCic.Rel _ ->
- let weak_gty = perforate_small subst metasenv context raw_gty in
- (*
- NCic.Appl (hd:: HExtlib.mk_list(NCic.Meta (0,(0,NCic.Irl 0)))
- (List.length tl)) in *)
- let more_cands =
- NDiscriminationTree.DiscriminationTree.retrieve_unifiables
- universe weak_gty
- in
- let smart_cands =
- NDiscriminationTree.TermSet.diff more_cands cands in
- let cic_weak_gty = mk_cic_term context weak_gty in
- let more_local_cands = search_in_th cic_weak_gty cache in
- let smart_local_cands =
- Ncic_termSet.diff more_local_cands local_cands in
- together smart_cands smart_local_cands
- (* together more_cands more_local_cands *)
- | _ -> []
- else []
+ (fun ty -> search_in_th ty cache)
+ Ncic_termSet.diff Ncic_termSet.empty gty weak_gty in
+ mapf g, mapf l
in
- let smart_candidates = sort_candidates status context smart_candidates in
- (* if smart then smart_candidates, []
- else candidates, [] *)
- candidates, smart_candidates
-;;
-
-let get_candidates ?(smart=true) flags status cache signature gty =
- match flags.candidates with
- | None -> get_candidates ~smart status cache signature gty
- | Some l -> l,[]
-;; *)
+ let local_cands,smart_local_cands =
+ if flags.local_candidates then local_cands,smart_local_cands
+ else let filter = List.filter (function Ast.NRef NReference.Ref (uri,_) -> is_a_needed_uri
+ (NUri.string_of_uri
+ uri) | _ -> false)
+ in filter local_cands,filter smart_local_cands
+ in
+ (* we now splits candidates in facts or not facts *)
+ let test = is_a_fact_ast status subst metasenv context in
+ let by,given_candidates =
+ match flags.candidates with
+ | Some l -> true, l
+ | None -> false, [] in
+(* we compute candidates to be applied in normal mode, splitted in
+ facts and not facts *)
+ let candidates_facts,candidates_other =
+ let gl1,gl2 = List.partition test global_cands in
+ let ll1,ll2 = List.partition test local_cands in
+ (* if the goal is an equation and paramodulation did not fail
+ we avoid to apply unit equalities; refl is an
+ exception since it prompts for convertibility *)
+ let l1 = if is_eq && (not pfailed)
+ then [Ast.Ident("refl",None)] else gl1@ll1 in
+ let l2 =
+ (* if smart given candidates are applied in smart mode *)
+ if by && smart then ll2
+ else if by then given_candidates@ll2
+ else gl2@ll2
+ in l1,l2
+ in
+ (* we now compute candidates to be applied in smart mode, splitted in
+ facts and not facts *)
+ let smart_candidates_facts, smart_candidates_other =
+ if is_prod || not(smart) then [],[]
+ else
+ let sgl1,sgl2 = List.partition test smart_global_cands in
+ let sll1,sll2 = List.partition test smart_local_cands in
+ let l1 = if is_eq then [] else sgl1@sll1 in
+ let l2 =
+ if by && smart then given_candidates@sll2
+ else if by then sll2
+ else sgl2@sll2
+ in l1,l2
+ in
+ candidates_facts,
+ smart_candidates_facts,
+ sort_candidates status context (candidates_other),
+ sort_candidates status context (smart_candidates_other)
+;;
-let applicative_case depth signature status flags gty cache =
+let applicative_case ~pfailed depth signature status flags gty cache =
app_counter:= !app_counter+1;
let _,_,metasenv,subst,_ = status#obj in
let context = ctx_of gty in
let tcache = cache.facts in
let is_prod, is_eq =
let status, t = term_of_cic_term status gty context in
- let t = NCicReduction.whd subst context t in
+ let t = NCicReduction.whd status subst context t in
match t with
- | NCic.Prod _ -> true, false
- | _ -> false, NCicParamod.is_equation metasenv subst context t
+ | NCic.Prod _ -> true, false
+ | _ -> false, NCicParamod.is_equation status metasenv subst context t
in
- debug_print~depth (lazy (string_of_bool is_eq));
- (* old
- let candidates, smart_candidates =
- get_candidates ~smart:(not is_eq) depth
- flags status tcache signature gty in
- (* if the goal is an equation we avoid to apply unit equalities,
- since superposition should take care of them; refl is an
- exception since it prompts for convertibility *)
- let candidates =
- let test x = not (is_a_fact_ast status subst metasenv context x) in
- if is_eq then
- Ast.Ident("refl",None) ::List.filter test candidates
- else candidates in *)
+ debug_print ~depth (lazy (string_of_bool is_eq));
(* new *)
- let candidates, smart_candidates =
- get_candidates ~smart:true depth
- flags status tcache signature gty in
- (* if the goal is an equation we avoid to apply unit equalities,
- since superposition should take care of them; refl is an
- exception since it prompts for convertibility *)
- let candidates,smart_candidates =
- let test x = not (is_a_fact_ast status subst metasenv context x) in
- if is_eq then
- Ast.Ident("refl",None) ::List.filter test candidates,
- List.filter test smart_candidates
- else candidates,smart_candidates in
- debug_print ~depth
- (lazy ("candidates: " ^ string_of_int (List.length candidates)));
- debug_print ~depth
- (lazy ("smart candidates: " ^
- string_of_int (List.length smart_candidates)));
- (*
- let sm = 0 in
- let smart_candidates = [] in *)
- let sm = if is_eq then 0 else 2 in
- let maxd = ((depth + 1) = flags.maxdepth) in
- let only_one = flags.last && maxd in
- debug_print (lazy ("only_one: " ^ (string_of_bool only_one)));
- debug_print (lazy ("maxd: " ^ (string_of_bool maxd)));
- let elems =
+ let candidates_facts, smart_candidates_facts,
+ candidates_other, smart_candidates_other =
+ get_candidates ~smart:true ~pfailed depth
+ flags status tcache signature gty
+ in
+ let sm = if is_eq || is_prod then 0 else 2 in
+ (*let sm1 = if flags.last then 2 else 0 in *)
+ let maxd = (depth + 1 = flags.maxdepth) in
+ let try_candidates only_one sm acc candidates =
List.fold_left
(fun elems cand ->
if (only_one && (elems <> [])) then elems
- else
- if (maxd && not(is_prod) &
- not(is_a_fact_ast status subst metasenv context cand))
- then (debug_print (lazy "pruned: not a fact"); elems)
else
match try_candidate (~smart:sm)
flags depth status cache.unit_eq context cand with
| None -> elems
| Some x -> x::elems)
- [] candidates
- in
- let more_elems =
- if only_one && elems <> [] then elems
- else
- List.fold_left
- (fun elems cand ->
- if (only_one && (elems <> [])) then elems
- else
- if (maxd && not(is_prod) &&
- not(is_a_fact_ast status subst metasenv context cand))
- then (debug_print (lazy "pruned: not a fact"); elems)
- else
- match try_candidate (~smart:1)
- flags depth status cache.unit_eq context cand with
- | None -> elems
- | Some x -> x::elems)
- [] smart_candidates
- in
- elems@more_elems
+ acc candidates
+ in
+ (* if the goal is the last one we stop at the first fact *)
+ let elems = try_candidates flags.last sm [] candidates_facts in
+ (* now we add smart_facts *)
+ let elems = try_candidates flags.last sm elems smart_candidates_facts in
+ (* if we are at maxdepth and the goal is not a product we are done
+ similarly, if the goal is the last one and we already found a
+ solution *)
+ if (maxd && not(is_prod)) || (flags.last && elems<>[]) then elems
+ else
+ let elems = try_candidates false 2 elems candidates_other in
+ debug_print ~depth (lazy ("not facts: try smart application"));
+ try_candidates false 2 elems smart_candidates_other
;;
exception Found
;;
(* gty is supposed to be meta-closed *)
-let is_subsumed depth status gty cache =
+let is_subsumed depth filter_depth status gty cache =
if cache=[] then false else (
debug_print ~depth (lazy("Subsuming " ^ (ppterm status gty)));
let n,h,metasenv,subst,obj = status#obj in
let ctx = ctx_of gty in
- let _ , target = term_of_cic_term status gty ctx in
- let target = NCicSubstitution.lift 1 target in
+ let _ , raw_gty = term_of_cic_term status gty ctx in
+ let target = NCicSubstitution.lift status 1 raw_gty in
+ (* we compute candidates using the perforated type *)
+ let weak_gty =
+ match target with
+ | NCic.Appl _
+ | NCic.Const _
+ | NCic.Rel _ ->
+ let raw_weak =
+ perforate_small status subst metasenv ctx raw_gty in
+ let weak = mk_cic_term ctx raw_weak in
+ debug_print ~depth (lazy ("weak_gty:" ^ NTacStatus.ppterm status weak));
+ Some (weak)
+ | _ -> None
+ in
(* candidates must only be searched w.r.t the given context *)
let candidates =
try
let idx = List.assq ctx cache in
- Ncic_termSet.elements
- (InvRelDiscriminationTree.retrieve_generalizations idx gty)
+ match weak_gty with
+ | Some weak ->
+ Ncic_termSet.elements
+ (InvRelDiscriminationTree.retrieve_unifiables idx weak)
+ |None -> []
with Not_found -> []
in
+ (* this is a dirty trick: the first argument of an application is used
+ to remember at which depth a goal failed *)
+ let filter t =
+ let ctx = ctx_of t in
+ let _, src = term_of_cic_term status t ctx in
+ match src with
+ | NCic.Appl [NCic.Implicit (`Typeof d); t]
+ when d <= depth -> Some (mk_cic_term ctx t)
+ | _ -> None in
+ let candidates =
+ if filter_depth then HExtlib.filter_map filter candidates else candidates in
debug_print ~depth
(lazy ("failure candidates: " ^ string_of_int (List.length candidates)));
try
NCicMetaSubst.mk_meta
metasenv ctx ~with_type:implication `IsType in
let status = status#set_obj (n,h,metasenv,subst,obj) in
- let status = status#set_stack [([1,Open j],[],[],`NoTag)] in
+ let status = status#set_stack [([1,Open j],[],[],`NoTag,[])] in
try
let status = NTactics.intro_tac "foo" status in
let status =
(match snd (term_of_cic_term status src ctx) with
| NCic.Const(NReference.Ref (_,NReference.Ind _) as r)
| NCic.Appl (NCic.Const(NReference.Ref (_,NReference.Ind _) as r)::_) ->
- let _,_,itys,_,_ = NCicEnvironment.get_checked_indtys r in
+ let _,_,itys,_,_ = NCicEnvironment.get_checked_indtys status r in
(match itys with
(* | [_,_,_,[_;_]] con nat va, ovviamente, in loop *)
| [_,_,_,[_]]
let intro ~depth status facts name =
let status = NTactics.intro_tac name status in
- let _, ctx, ngty = current_goal status in
+ let _, ctx, _ngty = current_goal status in
let t = mk_cic_term ctx (NCic.Rel 1) in
let status, keys = keys_of_term status t in
let facts = List.fold_left (add_to_th t) facts keys in
| _ -> status, facts
;;
-let intros ~depth status cache =
+let intros ~depth status ?(use_given_only=false) cache =
match is_prod status with
| `Inductive _
| `Some _ ->
- let trace = cache.trace in
+ let trace = cache.trace in
let status,facts =
intros_facts ~depth status cache.facts
in
[(0,Ast.Ident("__intros",None)),status], cache
else
(* we reindex the equation from scratch *)
- let unit_eq = index_local_equations status#eq_cache status in
+ let unit_eq = index_local_equations status#eq_cache status ~flag:use_given_only in
let status = NTactics.merge_tac status in
[(0,Ast.Ident("__intros",None)),status],
init_cache ~facts ~unit_eq () ~trace
let reduce ~whd ~depth status g =
let n,h,metasenv,subst,o = status#obj in
let attr, ctx, ty = NCicUtils.lookup_meta g metasenv in
- let ty = NCicUntrusted.apply_subst subst ctx ty in
+ let ty = NCicUntrusted.apply_subst status subst ctx ty in
let ty' =
- (if whd then NCicReduction.whd else NCicTacReduction.normalize) ~subst ctx ty
+ (if whd then NCicReduction.whd else NCicTacReduction.normalize) status ~subst ctx ty
in
if ty = ty' then []
else
(debug_print ~depth
- (lazy ("reduced to: "^ NCicPp.ppterm ctx subst metasenv ty'));
+ (lazy ("reduced to: "^ status#ppterm ctx subst metasenv ty'));
let metasenv =
(g,(attr,ctx,ty'))::(List.filter (fun (i,_) -> i<>g) metasenv)
in
[(!candidate_no,Ast.Ident("__whd",None)),status])
;;
-let do_something signature flags status g depth gty cache =
- let l0, cache = intros ~depth status cache in
+let is_meta status gty =
+ let _, ty = term_of_cic_term status gty (ctx_of gty) in
+ match ty with
+ | NCic.Meta _ -> true
+ | _ -> false
+;;
+
+let do_something signature flags status g depth gty ?(use_given_only=false) cache =
+ (* if the goal is meta we close it with I:True. This should work
+ thanks to the toplogical sorting of goals. *)
+ if is_meta status gty then
+ let t = Ast.Ident("I",None) in
+ debug_print (lazy ("using default term" ^ (NotationPp.pp_term status) t));
+ let s = NTactics.apply_tac ("",0,t) status in
+ [(0,t),s], cache
+ else
+ let l0, cache = intros ~depth status cache ~use_given_only in
if l0 <> [] then l0, cache
else
(* whd *)
- let l = (*reduce ~whd:true ~depth status g @*) reduce ~whd:true ~depth status g in
+ let l = reduce ~whd:true ~depth status g in
(* if l <> [] then l,cache else *)
(* backward aplications *)
let l1 =
in
let l2 =
if ((l1 <> []) && flags.last) then [] else
- applicative_case depth signature status flags gty cache
+ applicative_case ~pfailed:(l1=[]) depth signature status flags gty cache
in
(* statistics *)
List.iter
(* states in l1 have have an empty set of subgoals: no point to sort them *)
debug_print ~depth
(lazy ("alternatives = " ^ (string_of_int (List.length (l1@l@l2)))));
- (* l1 @ (sort_new_elems (l @ l2)), cache *)
- l1 @ (List.rev l2) @ l, cache
+ (* we order alternatives w.r.t the number of subgoals they open *)
+ l1 @ (sort_new_elems l2) @ l, cache
;;
let pp_goal = function
let gstatus =
match status#stack with
| [] -> assert false
- | (goals, t, k, tag) :: s ->
+ | (goals, t, k, tag, p) :: s ->
let g = head_goals status#stack in
let sortedg =
(List.rev (MS.topological_sort g (deps status))) in
- debug_print (lazy ("old g = " ^
+ noprint (lazy ("old g = " ^
String.concat "," (List.map string_of_int g)));
- debug_print (lazy ("sorted goals = " ^
+ noprint (lazy ("sorted goals = " ^
String.concat "," (List.map string_of_int sortedg)));
let is_it i = function
| (_,Continuationals.Stack.Open j )
let sorted_goals =
List.map (fun i -> List.find (is_it i) goals) sortedg
in
- (sorted_goals, t, k, tag) :: s
+ (sorted_goals, t, k, tag, p) :: s
in
status#set_stack gstatus
;;
let gstatus =
match status#stack with
| [] -> assert false
- | (g, t, k, tag) :: s ->
+ | (g, t, k, tag, p) :: s ->
let is_open = function
| (_,Continuationals.Stack.Open _) -> true
| (_,Continuationals.Stack.Closed _) -> false
in
let g' = List.filter is_open g in
- (g', t, k, tag) :: s
+ (g', t, k, tag, p) :: s
in
status#set_stack gstatus
;;
let rec slice level gs =
if level = 0 then [],[],gs else
match gs with
- | [] -> assert false
- | (g, t, k, tag) :: s ->
+ | [] -> assert false
+ | (g, t, k, tag,p) :: s ->
let f,o,gs = slice (level-1) s in
let f1,o1 = List.partition in_focus g
in
- (f1,[],[],`BranchTag)::f, (o1, t, k, tag)::o, gs
+ (f1,[],[],`BranchTag, [])::f, (o1, t, k, tag, p)::o, gs
in
let gstatus =
let f,o,s = slice level status#stack in f@o@s
status#set_stack gstatus
;;
-let rec stack_goals level gs =
- if level = 0 then []
- else match gs with
- | [] -> assert false
- | (g,_,_,_)::s ->
- let is_open = function
- | (_,Continuationals.Stack.Open i) -> Some i
- | (_,Continuationals.Stack.Closed _) -> None
- in
- HExtlib.filter_map is_open g @ stack_goals (level-1) s
-;;
-
-let open_goals level status = stack_goals level status#stack
-;;
-
let move_to_side level status =
match status#stack with
| [] -> assert false
- | (g,_,_,_)::tl ->
+ | (g,_,_,_,_)::tl ->
let is_open = function
| (_,Continuationals.Stack.Open i) -> Some i
| (_,Continuationals.Stack.Closed _) -> None
in
let others = menv_closure status (stack_goals (level-1) tl) in
List.for_all (fun i -> IntSet.mem i others)
- (HExtlib.filter_map is_open g)
+ (HExtlib.filter_map is_open g)
+
+let top_cache ~depth:_ top status ?(use_given_only=false) cache =
+ if top then
+ let unit_eq = index_local_equations status#eq_cache status ~flag:use_given_only in
+ {cache with unit_eq = unit_eq}
+ else cache
-let rec auto_clusters ?(top=false)
- flags signature cache depth status : unit =
+let rec auto_clusters ?(top=false) flags signature cache depth ?(use_given_only=false) status : unit =
debug_print ~depth (lazy ("entering auto clusters at depth " ^
- (string_of_int depth)));
- debug_print ~depth (pptrace cache.trace);
+ (string_of_int depth)));
+ debug_print ~depth (pptrace status cache.trace);
(* ignore(Unix.select [] [] [] 0.01); *)
let status = clean_up_tac status in
let goals = head_goals status#stack in
if depth = 0 then raise (Proved (status, cache.trace))
else
let status = NTactics.merge_tac status in
- let cache =
- let l,tree = cache.under_inspection in
- match l with
- | [] -> cache (* possible because of intros that cleans the cache *)
- | a::tl -> let tree = rm_from_th a tree a in
- {cache with under_inspection = tl,tree}
- in
- auto_clusters flags signature cache (depth-1) status
+ let cache =
+ let l,tree = cache.under_inspection in
+ match l with
+ | [] -> cache (* possible because of intros that cleans the cache *)
+ | a::tl -> let tree = rm_from_th a tree a in
+ {cache with under_inspection = tl,tree}
+ in
+ auto_clusters flags signature cache (depth-1) status ~use_given_only
else if List.length goals < 2 then
- auto_main flags signature cache depth status
+ let cache = top_cache ~depth top status cache ~use_given_only in
+ auto_main flags signature cache depth status ~use_given_only
else
let all_goals = open_goals (depth+1) status in
debug_print ~depth (lazy ("goals = " ^
String.concat "," (List.map string_of_int all_goals)));
let classes = HExtlib.clusters (deps status) all_goals in
- List.iter
- (fun gl ->
- if List.length gl > flags.maxwidth then
- (debug_print ~depth (lazy "FAIL GLOBAL WIDTH");
- raise (Gaveup IntSet.empty))
- else ()) classes;
+ (* if any of the classes exceed maxwidth we fail *)
+ List.iter
+ (fun gl ->
+ if List.length gl > flags.maxwidth then
+ begin
+ debug_print ~depth (lazy "FAIL GLOBAL WIDTH");
+ HLog.warn (sprintf "global width (%u) exceeded: %u"
+ flags.maxwidth (List.length gl));
+ raise (Gaveup cache.failures)
+ end else ()) classes;
if List.length classes = 1 then
let flags =
{flags with last = (List.length all_goals = 1)} in
- (* no need to cluster *)
- auto_main flags signature cache depth status
+ (* no need to cluster *)
+ let cache = top_cache ~depth top status cache ~use_given_only in
+ auto_main flags signature cache depth status ~use_given_only
else
- let classes = if top then List.rev classes else classes in
+ let classes = if top then List.rev classes else classes in
debug_print ~depth
(lazy
(String.concat "\n"
(List.map
- (fun l ->
- ("cluster:" ^ String.concat "," (List.map string_of_int l)))
+ (fun l ->
+ ("cluster:" ^ String.concat "," (List.map string_of_int l)))
classes)));
- let status,trace,b =
+ (* we now process each cluster *)
+ let status,cache,b =
List.fold_left
- (fun (status,trace,b) gl ->
- let cache = {cache with trace = trace} in
+ (fun (status,cache,b) gl ->
let flags =
{flags with last = (List.length gl = 1)} in
let lold = List.length status#stack in
- debug_print ~depth (lazy ("stack length = " ^
- (string_of_int lold)));
+ debug_print ~depth (lazy ("stack length = " ^
+ (string_of_int lold)));
let fstatus = deep_focus_tac (depth+1) gl status in
+ let cache = top_cache ~depth top fstatus cache ~use_given_only in
try
debug_print ~depth (lazy ("focusing on" ^
String.concat "," (List.map string_of_int gl)));
- auto_main flags signature cache depth fstatus; assert false
+ auto_main flags signature cache depth fstatus ~use_given_only; assert false
with
| Proved(status,trace) ->
- let status = NTactics.merge_tac status in
- let lnew = List.length status#stack in
- assert (lold = lnew);
- (status,trace,true)
- | Gaveup _ when top -> (status,trace,b)
+ let status = NTactics.merge_tac status in
+ let cache = {cache with trace = trace} in
+ let lnew = List.length status#stack in
+ assert (lold = lnew);
+ (status,cache,true)
+ | Gaveup failures when top ->
+ let cache = {cache with failures = failures} in
+ (status,cache,b)
)
- (status,cache.trace,false) classes
+ (status,cache,false) classes
in
let rec final_merge n s =
- if n = 0 then s else final_merge (n-1) (NTactics.merge_tac s)
+ if n = 0 then s else final_merge (n-1) (NTactics.merge_tac s)
in let status = final_merge depth status
- in if b then raise (Proved(status,trace)) else raise (Gaveup IntSet.empty)
+ in if b then raise (Proved(status,cache.trace)) else raise (Gaveup cache.failures)
and
(* BRAND NEW VERSION *)
-auto_main flags signature cache depth status: unit =
+auto_main flags signature cache depth ?(use_given_only=false) status: unit=
debug_print ~depth (lazy "entering auto main");
- debug_print ~depth (pptrace cache.trace);
+ debug_print ~depth (pptrace status cache.trace);
debug_print ~depth (lazy ("stack length = " ^
- (string_of_int (List.length status#stack))));
+ (string_of_int (List.length status#stack))));
(* ignore(Unix.select [] [] [] 0.01); *)
let status = sort_tac (clean_up_tac status) in
let goals = head_goals status#stack in
| a::tl -> let tree = rm_from_th a tree a in
{cache with under_inspection = tl,tree}
in
- auto_clusters flags signature cache (depth-1) status
- | orig::_ ->
+ auto_clusters flags signature cache (depth-1) status ~use_given_only
+ | _orig::_ ->
if depth > 0 && move_to_side depth status
then
let status = NTactics.merge_tac status in
| a::tl -> let tree = rm_from_th a tree a in
{cache with under_inspection = tl,tree}
in
- auto_clusters flags signature cache (depth-1) status
+ auto_clusters flags signature cache (depth-1) status ~use_given_only
else
let ng = List.length goals in
(* moved inside auto_clusters *)
- if ng > flags.maxwidth then
- (print ~depth (lazy "FAIL LOCAL WIDTH"); raise (Gaveup IntSet.empty))
- else if depth = flags.maxdepth then
- raise (Gaveup IntSet.empty)
+ if ng > flags.maxwidth then begin
+ debug_print ~depth (lazy "FAIL LOCAL WIDTH");
+ HLog.warn (sprintf "local width (%u) exceeded: %u"
+ flags.maxwidth ng);
+ raise (Gaveup cache.failures)
+ end else if depth = flags.maxdepth then
+ raise (Gaveup cache.failures)
else
let status = NTactics.branch_tac ~force:true status in
let g,gctx, gty = current_goal status in
let ctx,ty = close status g in
let closegty = mk_cic_term ctx ty in
let status, gty = apply_subst status gctx gty in
- debug_print ~depth (lazy("Attacking goal " ^ (string_of_int g) ^" : "^ppterm status gty));
- if is_subsumed depth status closegty (snd cache.under_inspection) then
+ debug_print ~depth (lazy("Attacking goal " ^
+ string_of_int g ^ " : "^ppterm status gty));
+ debug_print ~depth (lazy ("current failures: " ^
+ string_of_int (List.length (all_elements ctx cache.failures))));
+ let is_eq =
+ let _,_,metasenv,subst,_ = status#obj in
+ NCicParamod.is_equation status metasenv subst ctx ty in
+ (* if the goal is an equality we artificially raise its depth up to
+ flags.maxdepth - 1 *)
+ if (not flags.last && is_eq && (depth < (flags.maxdepth -2))) then
+ (* for efficiency reasons, in this case we severely cripple the
+ search depth *)
+ (debug_print ~depth (lazy ("RAISING DEPTH TO " ^ string_of_int (depth+1)));
+ auto_main flags signature cache (depth+1) status ~use_given_only)
+ (* check for loops *)
+ else if is_subsumed depth false status closegty (snd cache.under_inspection) then
(debug_print ~depth (lazy "SUBSUMED");
- raise (Gaveup IntSet.add g IntSet.empty))
+ raise (Gaveup cache.failures))
+ (* check for failures *)
+ else if is_subsumed depth true status closegty cache.failures then
+ (debug_print ~depth (lazy "ALREADY MET");
+ raise (Gaveup cache.failures))
else
- let new_sig = height_of_goal g status in
+ let new_sig = height_of_goal g status in
if new_sig < signature then
- (debug_print (lazy ("news = " ^ (string_of_int new_sig)));
- debug_print (lazy ("olds = " ^ (string_of_int signature))));
+ (debug_print ~depth (lazy ("news = " ^ (string_of_int new_sig)));
+ debug_print ~depth (lazy ("olds = " ^ (string_of_int signature))));
let alternatives, cache =
- do_something signature flags status g depth gty cache in
+ do_something signature flags status g depth gty cache ~use_given_only in
let loop_cache =
- let l,tree = cache.under_inspection in
- let l,tree = closegty::l, add_to_th closegty tree closegty in
- {cache with under_inspection = l,tree} in
- List.iter
- (fun ((_,t),status) ->
+ if flags.last then
+ let l,tree = cache.under_inspection in
+ let l,tree = closegty::l, add_to_th closegty tree closegty in
+ {cache with under_inspection = l,tree}
+ else cache in
+ let failures =
+ List.fold_left
+ (fun allfailures ((_,t),status) ->
debug_print ~depth
- (lazy ("(re)considering goal " ^
- (string_of_int g) ^" : "^ppterm status gty));
+ (lazy ("(re)considering goal " ^
+ (string_of_int g) ^" : "^ppterm status gty));
debug_print (~depth:depth)
- (lazy ("Case: " ^ CicNotationPp.pp_term t));
+ (lazy ("Case: " ^ NotationPp.pp_term status t));
let depth,cache =
- if t=Ast.Ident("__whd",None) ||
+ if t=Ast.Ident("__whd",None) ||
t=Ast.Ident("__intros",None)
then depth, cache
- else depth+1,loop_cache in
- let cache = add_to_trace ~depth cache t in
- try
- auto_clusters flags signature cache depth status
- with Gaveup _ ->
- debug_print ~depth (lazy "Failed");
- ())
- alternatives;
- raise (debug_print(lazy "no more candidates"); Gaveup IntSet.empty)
+ else depth+1,loop_cache in
+ let cache = add_to_trace status ~depth cache t in
+ let cache = {cache with failures = allfailures} in
+ try
+ auto_clusters flags signature cache depth status ~use_given_only;
+ assert false;
+ with Gaveup fail ->
+ debug_print ~depth (lazy "Failed");
+ fail)
+ cache.failures alternatives in
+ let failures =
+ if flags.last then
+ let newfail =
+ let dty = NCic.Appl [NCic.Implicit (`Typeof depth); ty] in
+ mk_cic_term ctx dty
+ in
+ (*prerr_endline ("FAILURE : " ^ ppterm status gty);*)
+ add_to_th newfail failures closegty
+ else failures in
+ debug_print ~depth (lazy "no more candidates");
+ raise (Gaveup failures)
;;
let int name l def =
(* filtering facts *)
in List.filter
(fun t ->
- match t with
- | Ast.NRef (NReference.Ref (u,_)) -> not (is_a_fact_obj s u)
- | _ -> false) trace
+ match t with
+ | Ast.NRef (NReference.Ref (u,_)) -> not (is_a_fact_obj s u)
+ | _ -> false) trace
;;
-let auto_tac ~params:(univ,flags) ?(trace_ref=ref []) status =
+(*CSC: TODO
+
+- auto_params e' una high tactic che prende in input i parametri e poi li
+ processa nel contesto vuoto calcolando i candidate
+
+- astrarla su una auto_params' che prende in input gia' i candidate e un
+ nuovo parametro per evitare il calcolo dei candidate locali che invece
+ diventano vuoti (ovvero: non usare automaticamente tutte le ipotesi, bensi'
+ nessuna)
+
+- reimplementi la auto_params chiamando la auto_params' con il flag a
+ false e il vecchio codice per andare da parametri a candiddati
+ OVVERO: usa tutti le ipotesi locali + candidati globali
+
+- crei un nuovo entry point lowtac che calcola i candidati usando il contesto
+ corrente e poi fa exec della auto_params' con i candidati e il flag a true
+ OVVERO: usa solo candidati globali che comprendono ipotesi locali
+*)
+
+type auto_params = NTacStatus.tactic_term list option * (string * string) list
+
+(*let auto_tac ~params:(univ,flags) ?(trace_ref=ref []) status =*)
+let auto_tac' candidates ~local_candidates ?(use_given_only=false) flags ?(trace_ref=ref []) status =
let oldstatus = status in
let status = (status:> NTacStatus.tac_status) in
let goals = head_goals status#stack in
let status, facts = mk_th_cache status goals in
- let unit_eq = index_local_equations status#eq_cache status in
- let cache = init_cache ~facts ~unit_eq () in
+(* let unit_eq = index_local_equations status#eq_cache status in *)
+ let cache = init_cache ~facts () in
(* pp_th status facts; *)
(*
NDiscriminationTree.DiscriminationTree.iter status#auto_cache (fun p t ->
debug_print (lazy(
NDiscriminationTree.NCicIndexable.string_of_path p ^ " |--> " ^
String.concat "\n " (List.map (
- NCicPp.ppterm ~metasenv:[] ~context:[] ~subst:[])
+ status#ppterm ~metasenv:[] ~context:[] ~subst:[])
(NDiscriminationTree.TermSet.elements t))
)));
*)
- let candidates =
- match univ with
- | None -> None
- | Some l ->
- let to_Ast t =
- let status, res = disambiguate status [] t None in
- let _,res = term_of_cic_term status res (ctx_of res)
- in Ast.NCic res
- in Some (List.map to_Ast l)
- in
let depth = int "depth" flags 3 in
let size = int "size" flags 10 in
let width = int "width" flags 4 (* (3+List.length goals)*) in
let flags = {
last = true;
candidates = candidates;
+ local_candidates = local_candidates;
maxwidth = width;
maxsize = size;
maxdepth = depth;
- timeout = Unix.gettimeofday() +. 3000.;
do_types = false;
} in
let initial_time = Unix.gettimeofday() in
app_counter:= 0;
let rec up_to x y =
if x > y then
- (print(lazy
+ (debug_print(lazy
("TIME ELAPSED:"^string_of_float(Unix.gettimeofday()-.initial_time)));
debug_print(lazy
("Applicative nodes:"^string_of_int !app_counter));
let _ = debug_print (lazy("\n\nRound "^string_of_int x^"\n")) in
let flags = { flags with maxdepth = x }
in
- try auto_clusters (~top:true) flags signature cache 0 status;assert false
+ try auto_clusters (~top:true) flags signature cache 0 status ~use_given_only;assert false
(*
try auto_main flags signature cache 0 status;assert false
*)
| Gaveup _ -> up_to (x+1) y
| Proved (s,trace) ->
debug_print (lazy ("proved at depth " ^ string_of_int x));
- List.iter (toref incr_uses statistics) trace;
+ List.iter (toref incr_uses statistics) trace;
let trace = cleanup_trace s trace in
- let _ = debug_print (pptrace trace) in
+ let _ = debug_print (pptrace status trace) in
let stack =
match s#stack with
- | (g,t,k,f) :: rest -> (filter_open g,t,k,f):: rest
+ | (g,t,k,f,p) :: rest -> (filter_open g,t,k,f,p):: rest
| _ -> assert false
in
let s = s#set_stack stack in
oldstatus#set_status s
in
let s = up_to depth depth in
- print (print_stat statistics);
+ debug_print (print_stat status statistics);
debug_print(lazy
("TIME ELAPSED:"^string_of_float(Unix.gettimeofday()-.initial_time)));
debug_print(lazy
s
;;
+let candidates_from_ctx univ ctx status =
+ match univ with
+ | None -> None
+ | Some l ->
+ let to_Ast t =
+ (* FG: `XTSort here? *)
+ let status, res = disambiguate status ctx t `XTNone in
+ let _,res = term_of_cic_term status res (ctx_of res)
+ in Ast.NCic res
+ in Some (List.map to_Ast l)
+(* FG: adding these lemmas to (List.map to_Ast l) slows auto very much in some cases
+ @ [Ast.Ident("refl",None); Ast.Ident("sym_eq",None);
+ Ast.Ident("trans_eq",None); Ast.Ident("eq_f",None);
+ Ast.Ident("eq_f2",None); Ast.Ident("eq_f3",None);
+ Ast.Ident("rewrite_r",None); Ast.Ident("rewrite_l",None)
+ ]
+*)
+
+let auto_lowtac ~params:(univ,flags) status goal =
+ let gty = get_goalty status goal in
+ let ctx = ctx_of gty in
+ let candidates = candidates_from_ctx univ ctx status in
+ auto_tac' candidates ~local_candidates:true ~use_given_only:false flags ~trace_ref:(ref [])
+
+let auto_tac ~params:(univ,flags) ?(trace_ref=ref []) status =
+ let candidates = candidates_from_ctx univ [] status in
+ auto_tac' candidates ~local_candidates:true ~use_given_only:false flags ~trace_ref status
+
+let auto_tac ~params:(_,flags as params) ?trace_ref =
+ if List.mem_assoc "demod" flags then
+ demod_tac ~params
+ else if List.mem_assoc "paramod" flags then
+ paramod_tac ~params
+ else if List.mem_assoc "fast_paramod" flags then
+ fast_eq_check_tac ~params
+ else auto_tac ~params ?trace_ref
+;;