module Ref = NReference
+type ctx =
+ | Ce of (NCic.hypothesis * NCic.obj list) Lazy.t
+ | Fix of (Ref.reference * string * NCic.term) Lazy.t
+
+let strictify =
+ function
+ Ce l -> `Ce (Lazy.force l)
+ | Fix l -> `Fix (Lazy.force l)
+;;
+
+(***** A function to restrict the context of a term getting rid of unsed
+ variables *******)
+
+let restrict octx ctx ot =
+ let odummy = Cic.Implicit None in
+ let dummy = NCic.Meta (~-1,(0,NCic.Irl 0)) in
+ let rec aux m acc ot t =
+ function
+ [],[] -> (ot,t),acc
+ | ohe::otl as octx,he::tl ->
+ if CicTypeChecker.does_not_occur octx 0 1 ot then
+ aux (m+1) acc (CicSubstitution.subst odummy ot)
+ (NCicSubstitution.subst dummy t) (otl,tl)
+ else
+ (match ohe,strictify he with
+ None,_ -> assert false
+ | Some (name,Cic.Decl oty),`Ce ((name', NCic.Decl ty),objs) ->
+ aux (m+1) ((m+1,objs,None)::acc) (Cic.Lambda (name,oty,ot))
+ (NCic.Lambda (name',ty,t)) (otl,tl)
+ | Some (name,Cic.Decl oty),`Fix (ref,name',ty) ->
+ aux (m+1) ((m+1,[],Some ref)::acc) (Cic.Lambda (name,oty,ot))
+ (NCic.Lambda (name',ty,t)) (otl,tl)
+ | Some (name,Cic.Def (obo,oty)),`Ce ((name', NCic.Def (bo,ty)),objs) ->
+ aux (m+1) ((m+1,objs,None)::acc) (Cic.LetIn (name,obo,oty,ot))
+ (NCic.LetIn (name',bo,ty,t)) (otl,tl)
+ | _,_ -> assert false)
+ | _,_ -> assert false in
+ let rec split_lambdas_and_letins octx ctx infos (ote,te) =
+ match infos, ote, te with
+ ([], _, _) -> octx,ctx,ote
+ | ((_,objs,None)::tl, Cic.Lambda(name,oso,ota), NCic.Lambda(name',so,ta)) ->
+ split_lambdas_and_letins ((Some(name,(Cic.Decl oso)))::octx)
+ (Ce (lazy ((name',NCic.Decl so),objs))::ctx) tl (ota,ta)
+ | ((_,objs,Some r)::tl,Cic.Lambda(name,oso,ota),NCic.Lambda(name',so,ta)) ->
+ split_lambdas_and_letins ((Some(name,(Cic.Decl oso)))::octx)
+ (Fix (lazy (r,name',so))::ctx) tl (ota,ta)
+ | ((_,objs,None)::tl,Cic.LetIn(name,obo,oty,ota),NCic.LetIn(nam',bo,ty,ta))->
+ split_lambdas_and_letins ((Some (name,(Cic.Def (obo,oty))))::octx)
+ (Ce (lazy ((nam',NCic.Def (bo,ty)),objs))::ctx) tl (ota,ta)
+ | (_, _, _) -> assert false
+ in
+ let long_t,infos = aux 0 [] ot dummy (octx,ctx) in
+ let clean_octx,clean_ctx,clean_ot= split_lambdas_and_letins [] [] infos long_t
+ in
+(*prerr_endline ("RESTRICT PRIMA: " ^ CicPp.pp ot (List.map (function None -> None | Some (name,_) -> Some name) octx));
+prerr_endline ("RESTRICT DOPO: " ^ CicPp.pp clean_ot (List.map (function None -> None | Some (name,_) -> Some name) clean_octx));
+*)
+ clean_octx,clean_ctx,clean_ot, List.map (fun (rel,_,_) -> rel) infos
+;;
+
+
+(**** The translation itself ****)
+
let cn_to_s = function
| Cic.Anonymous -> "_"
| Cic.Name s -> s
;;
-type ctx =
- | Ce of NCic.hypothesis
- | Fix of Ref.reference * string * NCic.term
-
let splat mk_pi ctx t =
List.fold_left
- (fun t c ->
- match c with
- | Ce (name, NCic.Def (bo,ty)) -> NCic.LetIn (name, ty, bo, t)
- | Ce (name, NCic.Decl ty) when mk_pi -> NCic.Prod (name, ty, t)
- | Ce (name, NCic.Decl ty) -> NCic.Lambda (name, ty, t)
- | Fix (_,name,ty) when mk_pi -> NCic.Prod (name, ty, t)
- | Fix (_,name,ty) -> NCic.Lambda (name,ty,t))
- t ctx
+ (fun (t,l) c ->
+ match strictify c with
+ | `Ce ((name, NCic.Def (bo,ty)),l') -> NCic.LetIn (name, ty, bo, t),l@l'
+ | `Ce ((name, NCic.Decl ty),l') when mk_pi -> NCic.Prod (name, ty, t),l@l'
+ | `Ce ((name, NCic.Decl ty),l') -> NCic.Lambda (name, ty, t),l@l'
+ | `Fix (_,name,ty) when mk_pi -> NCic.Prod (name, ty, t),l
+ | `Fix (_,name,ty) -> NCic.Lambda (name,ty,t),l)
+ (t,[]) ctx
;;
let context_tassonomy ctx =
let rec split inner acc acc1 = function
| Ce _ :: tl when inner -> split inner (acc+1) (acc1+1) tl
| Fix _ ::tl -> split false acc (acc1+1) tl
- | _ as l -> acc, List.length l, acc1
+ | _ as l ->
+ let only_decl () =
+ List.filter
+ (function
+ Ce _ as ce ->
+ (match strictify ce with
+ `Ce ((_, NCic.Decl _),_) -> true
+ | _ -> false)
+ | Fix _ -> true) l
+ in
+ acc, List.length l, lazy (List.length (only_decl ())), acc1
in
split true 0 1 ctx
;;
-let splat_args_for_rel ctx t =
- let bound, free, primo_ce_dopo_fix = context_tassonomy ctx in
+let splat_args_for_rel ctx t ?rels n_fix =
+ let rels =
+ match rels with
+ Some rels -> rels
+ | None ->
+ let rec mk_irl = function 0 -> [] | n -> n::mk_irl (n - 1) in
+ mk_irl (List.length ctx)
+ in
+ let bound, free, _, primo_ce_dopo_fix = context_tassonomy ctx in
if free = 0 then t
else
let rec aux = function
- | 0 -> []
- | n ->
- (match List.nth ctx (n+bound) with
- | Fix (refe, _, _) when (n+bound) < primo_ce_dopo_fix -> NCic.Const refe
- | Fix _ | Ce _ -> NCic.Rel (n+bound)) :: aux (n-1)
+ | n,_ when n = bound + n_fix -> []
+ | n,he::tl ->
+ (match strictify (List.nth ctx (n-1)) with
+ | `Fix (refe, _, _) when n < primo_ce_dopo_fix ->
+ NCic.Const refe :: aux (n-1,tl)
+ | `Fix _ | `Ce ((_, NCic.Decl _),_) ->
+ NCic.Rel (he - n_fix)::aux(n-1,tl)
+ | `Ce ((_, NCic.Def _),_) -> aux (n-1,tl))
+ | _,_ -> assert false
in
- NCic.Appl (t:: aux free)
+ let args = aux (List.length ctx,rels) in
+ match args with
+ [] -> t
+ | _::_ -> NCic.Appl (t::args)
;;
-let splat_args ctx t n_fix =
- let bound, free, primo_ce_dopo_fix = context_tassonomy ctx in
+let splat_args ctx t n_fix rels =
+ let bound, free, _, primo_ce_dopo_fix = context_tassonomy ctx in
if ctx = [] then t
else
let rec aux = function
- | 0 -> []
- | n ->
- (match List.nth ctx (n-1) with
- | Ce _ when n <= bound -> NCic.Rel n
- | Fix (refe, _, _) when n < primo_ce_dopo_fix ->
- splat_args_for_rel ctx (NCic.Const refe)
- | Fix _ | Ce _ -> NCic.Rel (n - n_fix)
- ) :: aux (n-1)
+ | 0,[] -> []
+ | n,he::tl ->
+ (match strictify (List.nth ctx (n-1)) with
+ | `Ce ((_, NCic.Decl _),_) when n <= bound ->
+ NCic.Rel he:: aux (n-1,tl)
+ | `Fix (refe, _, _) when n < primo_ce_dopo_fix ->
+ splat_args_for_rel ctx (NCic.Const refe) ~rels n_fix :: aux (n-1,tl)
+ | `Fix _ | `Ce((_, NCic.Decl _),_)-> NCic.Rel (he - n_fix)::aux(n-1,tl)
+ | `Ce ((_, NCic.Def _),_) -> aux (n - 1,tl)
+ )
+ | _,_ -> assert false
in
- NCic.Appl (t:: aux (List.length ctx))
+ NCic.Appl (t:: aux ((List.length ctx,rels)))
;;
exception Nothing_to_do;;
aux [] t
;;
+let get_fresh,reset_seed =
+ let seed = ref 0 in
+ (function () ->
+ incr seed;
+ string_of_int !seed),
+ (function () -> seed := 0)
+;;
+
+exception NotSimilar
+let alpha t1 t2 ref ref' =
+ let rec aux t1 t2 = match t1,t2 with
+ | NCic.Rel n, NCic.Rel m when n=m -> ()
+ | NCic.Appl l1, NCic.Appl l2 -> List.iter2 aux l1 l2
+ | NCic.Lambda (_,s1,t1), NCic.Lambda (_,s2,t2)
+ | NCic.Prod (_,s1,t1), NCic.Prod (_,s2,t2) -> aux s1 s2; aux t1 t2
+ | NCic.LetIn (_,s1,ty1,t1), NCic.LetIn (_,s2,ty2,t2) ->
+ aux s1 s2; aux ty1 ty2; aux t1 t2
+ | NCic.Const (NReference.Ref (_,uu1,xp1)),
+ NCic.Const (NReference.Ref (_,uu2,xp2)) when
+ let NReference.Ref (_,u1,_) = ref in
+ let NReference.Ref (_,u2,_) = ref' in
+ NUri.eq uu1 u1 && NUri.eq uu2 u2 && xp1 = xp2
+ -> ()
+ | NCic.Const r1, NCic.Const r2 when NReference.eq r1 r2 -> ()
+ | NCic.Meta _,NCic.Meta _ -> ()
+ | NCic.Implicit _,NCic.Implicit _ -> ()
+ | NCic.Sort x,NCic.Sort y when x=y -> ()
+ | NCic.Match (_,t1,t11,tl1), NCic.Match (_,t2,t22,tl2) ->
+ aux t1 t2;aux t11 t22;List.iter2 aux tl1 tl2
+ | _-> raise NotSimilar
+ in
+ try aux t1 t2; true with NotSimilar -> false
+;;
+
+exception Found of NReference.reference;;
+let cache = Hashtbl.create 313;;
+let same_obj ref ref' =
+ function
+ | (_,_,_,_,NCic.Fixpoint (_,l1,_)), (_,_,_,_,NCic.Fixpoint (_,l2,_))
+ when List.for_all2 (fun (_,_,_,ty1,bo1) (_,_,_,ty2,bo2) ->
+ alpha ty1 ty2 ref ref' && alpha bo1 bo2 ref ref') l1 l2 ->
+ true
+ | _ -> false
+;;
+let find_in_cache name obj ref =
+ try
+ List.iter
+ (function (ref',obj') ->
+ let recno, fixno =
+ match ref with
+ NReference.Ref (_,_,NReference.Fix (fixno,recno)) -> recno,fixno
+ | _ -> assert false in
+ let recno',fixno' =
+ match ref' with
+ NReference.Ref (_,_,NReference.Fix (fixno',recno)) -> recno,fixno'
+ | _ -> assert false in
+ if recno = recno' && fixno = fixno' && same_obj ref ref' (obj,obj') then (
+(*
+prerr_endline ("!!!!!!!!!!! CACHE HIT !!!!!!!!!!\n" ^
+NReference.string_of_reference ref ^ "\n" ^
+NReference.string_of_reference ref' ^ "\n");
+ *)
+ raise (Found ref'));
+(*
+prerr_endline ("CACHE SAME NAME: " ^ NReference.string_of_reference ref ^ " <==> " ^ NReference.string_of_reference ref');
+ *)
+ ) (Hashtbl.find_all cache name);
+(* prerr_endline "<<< CACHE MISS >>>"; *)
+ begin
+ match obj, ref with
+ | (_,_,_,_,NCic.Fixpoint (true,fl,_)) , NReference.Ref (x,y,NReference.Fix _) ->
+ ignore(List.fold_left (fun i (_,name,rno,_,_) ->
+ let ref = NReference.mk_fix i rno ref in
+ Hashtbl.add cache name (ref,obj);
+ i+1
+ ) 0 fl)
+ | _ -> assert false
+ end;
+ None
+ with Found ref -> Some ref
+;;
+
(* we are lambda-lifting also variables that do not occur *)
(* ctx does not distinguish successive blocks of cofix, since there may be no
* lambda separating them *)
let convert_term uri t =
- let rec aux octx (ctx : ctx list) n_fix uri = function
- | Cic.CoFix (k, fl) ->
+ (* k=true if we are converting a term to be pushed in a ctx or if we are
+ converting the type of a fix;
+ k=false if we are converting a term to be put in the body of a fix;
+ in the latter case, we must permute Rels since the Fix abstraction will
+ preceed its lefts parameters; in the former case, there is nothing to
+ permute *)
+ let rec aux k octx (ctx : ctx list) n_fix uri = function
+ | Cic.CoFix _ as cofix ->
+ let octx,ctx,fix,rels = restrict octx ctx cofix in
+ let cofixno,fl =
+ match fix with Cic.CoFix (cofixno,fl)->cofixno,fl | _-> assert false in
let buri =
UriManager.uri_of_string
(UriManager.buri_of_uri uri^"/"^
- UriManager.name_of_uri uri ^ "___" ^
- string_of_int (List.length ctx)^".con")
+ UriManager.name_of_uri uri ^ "___" ^ get_fresh () ^ ".con")
in
let bctx, fixpoints_tys, tys, _ =
List.fold_right
- (fun (name,ty,_) (ctx, fixpoints, tys, idx) ->
- let ty, fixpoints_ty = aux octx ctx n_fix uri ty in
+ (fun (name,ty,_) (bctx, fixpoints, tys, idx) ->
+ let ty, fixpoints_ty = aux true octx ctx n_fix uri ty in
let r = Ref.reference_of_ouri buri(Ref.CoFix idx) in
- Fix (r,name,ty) :: ctx, fixpoints_ty @ fixpoints,ty::tys,idx+1)
- fl ([], [], [], 0)
+ bctx @ [Fix (lazy (r,name,ty))],
+ fixpoints_ty @ fixpoints,ty::tys,idx-1)
+ fl ([], [], [], List.length fl-1)
in
let bctx = bctx @ ctx in
let n_fl = List.length fl in
let fl, fixpoints =
List.fold_right2
(fun (name,_,bo) ty (l,fixpoints) ->
- let bo, fixpoints_bo = aux boctx bctx n_fl buri bo in
- (([],name,~-1,splat true ctx ty, splat false ctx bo)::l),
- fixpoints_bo @ fixpoints)
+ let bo, fixpoints_bo = aux false boctx bctx n_fl buri bo in
+ let splty,fixpoints_splty = splat true ctx ty in
+ let splbo,fixpoints_splbo = splat false ctx bo in
+ (([],name,~-1,splty,splbo)::l),
+ fixpoints_bo @ fixpoints_splty @ fixpoints_splbo @ fixpoints)
fl tys ([],fixpoints_tys)
in
let obj =
NCic.Fixpoint (false, fl, (`Generated, `Definition))
in
splat_args ctx
- (NCic.Const (Ref.reference_of_ouri buri (Ref.CoFix k)))
- n_fix,
+ (NCic.Const (Ref.reference_of_ouri buri (Ref.CoFix cofixno)))
+ n_fix rels,
fixpoints @ [obj]
- | Cic.Fix (k, fl) ->
+ | Cic.Fix _ as fix ->
+ let octx,ctx,fix,rels = restrict octx ctx fix in
+ let fixno,fl =
+ match fix with Cic.Fix (fixno,fl) -> fixno,fl | _ -> assert false in
let buri =
UriManager.uri_of_string
(UriManager.buri_of_uri uri^"/"^
- UriManager.name_of_uri uri ^ "___" ^
- string_of_int (List.length ctx)^".con")
+ UriManager.name_of_uri uri ^ "___" ^ get_fresh () ^ ".con")
in
let bad_bctx, fixpoints_tys, tys, _ =
List.fold_right
(fun (name,recno,ty,_) (bctx, fixpoints, tys, idx) ->
- let ty, fixpoints_ty = aux octx ctx n_fix uri ty in
+ let ty, fixpoints_ty = aux true octx ctx n_fix uri ty in
let r = (* recno is dummy here, must be lifted by the ctx len *)
Ref.reference_of_ouri buri (Ref.Fix (idx,recno))
in
- Fix (r,name,ty) :: bctx, fixpoints_ty@fixpoints,ty::tys,idx+1)
- fl ([], [], [], 0)
+ bctx @ [Fix (lazy (r,name,ty))],
+ fixpoints_ty@fixpoints,ty::tys,idx-1)
+ fl ([], [], [], List.length fl-1)
in
- let _, free, _ = context_tassonomy (bad_bctx @ ctx) in
+ let _, _, free_decls, _ = context_tassonomy (bad_bctx @ ctx) in
+ let free_decls = Lazy.force free_decls in
let bctx =
- List.map (function
- | Fix (Ref.Ref (_,_,Ref.Fix (idx, recno)),name, ty) ->
- Fix (Ref.reference_of_ouri buri(Ref.Fix (idx,recno+free)),name,ty)
+ List.map (function ce -> match strictify ce with
+ | `Fix (Ref.Ref (_,_,Ref.Fix (idx, recno)),name, ty) ->
+ Fix (lazy (Ref.reference_of_ouri buri
+ (Ref.Fix (idx,recno+free_decls)),name,ty))
| _ -> assert false) bad_bctx @ ctx
in
let n_fl = List.length fl in
(Some (Cic.Name n,(Cic.Decl (CicSubstitution.lift len ty)))::types,
len+1)) (octx,0) fl
in
- let rno_k = ref 0 in
+ let rno_fixno = ref 0 in
let fl, fixpoints,_ =
List.fold_right2
(fun (name,rno,_,bo) ty (l,fixpoints,idx) ->
- let bo, fixpoints_bo = aux boctx bctx n_fl buri bo in
- let rno = rno + free in
- if idx = k then rno_k := rno;
- (([],name,rno,splat true ctx ty, splat false ctx bo)::l),
- fixpoints_bo @ fixpoints,idx+1)
+ let bo, fixpoints_bo = aux false boctx bctx n_fl buri bo in
+ let splty,fixpoints_splty = splat true ctx ty in
+ let splbo,fixpoints_splbo = splat false ctx bo in
+ let rno = rno + free_decls in
+ if idx = fixno then rno_fixno := rno;
+ (([],name,rno,splty,splbo)::l),
+ fixpoints_bo@fixpoints_splty@fixpoints_splbo@fixpoints,idx+1)
fl tys ([],fixpoints_tys,0)
in
let obj =
NUri.nuri_of_ouri buri,max_int,[],[],
- NCic.Fixpoint (true, fl, (`Generated, `Definition))
+ NCic.Fixpoint (true, fl, (`Generated, `Definition)) in
+ let r = Ref.reference_of_ouri buri (Ref.Fix (fixno,!rno_fixno)) in
+ let obj,r =
+ let _,name,_,_,_ = List.nth fl fixno in
+ match find_in_cache name obj r with
+ Some r' -> [],r'
+ | None -> [obj],r
in
- splat_args ctx
- (NCic.Const
- (Ref.reference_of_ouri buri (Ref.Fix (k,!rno_k))))
- n_fix,
- fixpoints @ [obj]
+ splat_args ctx (NCic.Const r) n_fix rels, fixpoints @ obj
| Cic.Rel n ->
- let bound, _, primo_ce_dopo_fix = context_tassonomy ctx in
+ let bound, _, _, primo_ce_dopo_fix = context_tassonomy ctx in
(match List.nth ctx (n-1) with
- | Fix (r,_,_) when n < primo_ce_dopo_fix ->
- splat_args_for_rel ctx (NCic.Const r), []
+ | Fix l when n < primo_ce_dopo_fix ->
+ let r,_,_ = Lazy.force l in
+ splat_args_for_rel ctx (NCic.Const r) n_fix, []
| Ce _ when n <= bound -> NCic.Rel n, []
- | Fix _ (* BUG 3 fix nested *)
- | Ce _ -> NCic.Rel (n-n_fix), [])
+ | Fix _ when n <= bound -> assert false
+ | Fix _ | Ce _ when k = true -> NCic.Rel n, []
+ | Fix _ | Ce _ -> NCic.Rel (n-n_fix), [])
| Cic.Lambda (name, (s as old_s), t) ->
- let s, fixpoints_s = aux octx ctx n_fix uri s in
- let ctx = Ce (cn_to_s name, NCic.Decl s) :: ctx in
+ let s, fixpoints_s = aux k octx ctx n_fix uri s in
+ let s'_and_fixpoints_s' = lazy (aux true octx ctx n_fix uri old_s) in
+ let ctx =
+ Ce (lazy
+ let s',fixpoints_s' = Lazy.force s'_and_fixpoints_s' in
+ ((cn_to_s name, NCic.Decl s'),fixpoints_s'))::ctx in
let octx = Some (name, Cic.Decl old_s) :: octx in
- let t, fixpoints_t = aux octx ctx n_fix uri t in
+ let t, fixpoints_t = aux k octx ctx n_fix uri t in
NCic.Lambda (cn_to_s name, s, t), fixpoints_s @ fixpoints_t
| Cic.Prod (name, (s as old_s), t) ->
- let s, fixpoints_s = aux octx ctx n_fix uri s in
- let ctx = Ce (cn_to_s name, NCic.Decl s) :: ctx in
+ let s, fixpoints_s = aux k octx ctx n_fix uri s in
+ let s'_and_fixpoints_s' = lazy (aux true octx ctx n_fix uri old_s) in
+ let ctx =
+ Ce (lazy
+ let s',fixpoints_s' = Lazy.force s'_and_fixpoints_s' in
+ ((cn_to_s name, NCic.Decl s'),fixpoints_s'))::ctx in
let octx = Some (name, Cic.Decl old_s) :: octx in
- let t, fixpoints_t = aux octx ctx n_fix uri t in
+ let t, fixpoints_t = aux k octx ctx n_fix uri t in
NCic.Prod (cn_to_s name, s, t), fixpoints_s @ fixpoints_t
| Cic.LetIn (name, (te as old_te), (ty as old_ty), t) ->
- let te, fixpoints_s = aux octx ctx n_fix uri te in
- let ty, fixpoints_ty = aux octx ctx n_fix uri ty in
- let ctx = Ce (cn_to_s name, NCic.Def (te, ty)) :: ctx in
+ let te, fixpoints_s = aux k octx ctx n_fix uri te in
+ let te_and_fixpoints_s' = lazy (aux true octx ctx n_fix uri old_te) in
+ let ty, fixpoints_ty = aux k octx ctx n_fix uri ty in
+ let ty_and_fixpoints_ty' = lazy (aux true octx ctx n_fix uri old_ty) in
+ let ctx =
+ Ce (lazy
+ let te',fixpoints_s' = Lazy.force te_and_fixpoints_s' in
+ let ty',fixpoints_ty' = Lazy.force ty_and_fixpoints_ty' in
+ let fixpoints' = fixpoints_s' @ fixpoints_ty' in
+ ((cn_to_s name, NCic.Def (te', ty')),fixpoints'))::ctx in
let octx = Some (name, Cic.Def (old_te, old_ty)) :: octx in
- let t, fixpoints_t = aux octx ctx n_fix uri t in
+ let t, fixpoints_t = aux k octx ctx n_fix uri t in
NCic.LetIn (cn_to_s name, ty, te, t),
fixpoints_s @ fixpoints_t @ fixpoints_ty
| Cic.Cast (t,ty) ->
- let t, fixpoints_t = aux octx ctx n_fix uri t in
- let ty, fixpoints_ty = aux octx ctx n_fix uri ty in
+ let t, fixpoints_t = aux k octx ctx n_fix uri t in
+ let ty, fixpoints_ty = aux k octx ctx n_fix uri ty in
NCic.LetIn ("cast", ty, t, NCic.Rel 1), fixpoints_t @ fixpoints_ty
| Cic.Sort Cic.Prop -> NCic.Sort NCic.Prop,[]
| Cic.Sort Cic.CProp -> NCic.Sort NCic.CProp,[]
- | Cic.Sort (Cic.Type _) -> NCic.Sort (NCic.Type 0),[]
+ | Cic.Sort (Cic.Type u) ->
+ NCic.Sort (NCic.Type (CicUniv.get_rank u)),[]
| Cic.Sort Cic.Set -> NCic.Sort (NCic.Type 0),[]
(* calculate depth in the univ_graph*)
| Cic.Appl l ->
let l, fixpoints =
List.fold_right
(fun t (l,acc) ->
- let t, fixpoints = aux octx ctx n_fix uri t in
+ let t, fixpoints = aux k octx ctx n_fix uri t in
(t::l,fixpoints@acc))
l ([],[])
in
| (NCic.Appl l1)::l2 -> NCic.Appl (l1@l2), fixpoints
| _ -> NCic.Appl l, fixpoints)
| Cic.Const (curi, ens) ->
- aux_ens curi octx ctx n_fix uri ens
+ aux_ens k curi octx ctx n_fix uri ens
(match fst(CicEnvironment.get_obj CicUniv.oblivion_ugraph curi) with
| Cic.Constant (_,Some _,_,_,_) ->
NCic.Const (Ref.reference_of_ouri curi Ref.Def)
NCic.Const (Ref.reference_of_ouri curi Ref.Decl)
| _ -> assert false)
| Cic.MutInd (curi, tyno, ens) ->
- aux_ens curi octx ctx n_fix uri ens
+ aux_ens k curi octx ctx n_fix uri ens
(NCic.Const (Ref.reference_of_ouri curi (Ref.Ind tyno)))
| Cic.MutConstruct (curi, tyno, consno, ens) ->
- aux_ens curi octx ctx n_fix uri ens
+ aux_ens k curi octx ctx n_fix uri ens
(NCic.Const (Ref.reference_of_ouri curi (Ref.Con (tyno,consno))))
+ | Cic.Var (curi, ens) ->
+ (match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph curi) with
+ Cic.Variable (_,Some bo,_,_,_) ->
+ aux k octx ctx n_fix uri (CicSubstitution.subst_vars ens bo)
+ | _ -> assert false)
| Cic.MutCase (curi, tyno, outty, t, branches) ->
let r = Ref.reference_of_ouri curi (Ref.Ind tyno) in
- let outty, fixpoints_outty = aux octx ctx n_fix uri outty in
- let t, fixpoints_t = aux octx ctx n_fix uri t in
+ let outty, fixpoints_outty = aux k octx ctx n_fix uri outty in
+ let t, fixpoints_t = aux k octx ctx n_fix uri t in
let branches, fixpoints =
List.fold_right
(fun t (l,acc) ->
- let t, fixpoints = aux octx ctx n_fix uri t in
+ let t, fixpoints = aux k octx ctx n_fix uri t in
(t::l,fixpoints@acc))
branches ([],[])
in
NCic.Match (r,outty,t,branches), fixpoints_outty@fixpoints_t@fixpoints
- | Cic.Implicit _ | Cic.Meta _ | Cic.Var _ -> assert false
- and aux_ens curi octx ctx n_fix uri ens he =
+ | Cic.Implicit _ | Cic.Meta _ -> assert false
+ and aux_ens k curi octx ctx n_fix uri ens he =
match ens with
[] -> he,[]
| _::_ ->
in
let ens,objs =
List.fold_right
- (fun uri (l,objs) ->
- let t = List.assoc uri ens in
- let t,o = aux octx ctx n_fix uri t in
- t::l, o@objs
+ (fun luri (l,objs) ->
+ match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph luri) with
+ Cic.Variable (_,Some _,_,_,_) -> l, objs
+ | Cic.Variable (_,None,_,_,_) ->
+ let t = List.assoc luri ens in
+ let t,o = aux k octx ctx n_fix uri t in
+ t::l, o@objs
+ | _ -> assert false
) params ([],[])
in
- NCic.Appl (he::ens),objs
+ match ens with
+ [] -> he,objs
+ | _::_ -> NCic.Appl (he::ens),objs
in
- aux [] [] 0 uri t
+ aux false [] [] 0 uri t
;;
let cook mode vars t =
([], name, ty, cl)::itl, fix_ty @ fix_cl @ acc)
itl ([],[])
in
- NCic.Inductive(ind, leftno + List.length vars, itl, (`Provided, `Regular)),
+ NCic.Inductive(ind, leftno + List.length
+ (List.filter (fun v ->
+ match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph v) with
+ Cic.Variable (_,Some _,_,_,_) -> false
+ | Cic.Variable (_,None,_,_,_) -> true
+ | _ -> assert false)
+ vars)
+ , itl, (`Provided, `Regular)),
fix_itl
| Cic.Variable _
| Cic.CurrentProof _ -> assert false
;;
let convert_obj uri obj =
+ reset_seed ();
let o, fixpoints = convert_obj_aux uri obj in
let obj = NUri.nuri_of_ouri uri,max_int, [], [], o in
fixpoints @ [obj]