X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;f=helm%2Fsoftware%2Fcomponents%2Fng_kernel%2FoCic2NCic.ml;h=2738b1c901835183078c7a24b0f3470475f13f02;hb=1b70a1f66be53f76e475383e86d63c2b5c1fbcaa;hp=bb5862fda85f5981516944e860cd9a3db06175c3;hpb=8a49ad7c7475e5486ea9ecacc82a07b15fcded6e;p=helm.git diff --git a/helm/software/components/ng_kernel/oCic2NCic.ml b/helm/software/components/ng_kernel/oCic2NCic.ml index bb5862fda..2738b1c90 100644 --- a/helm/software/components/ng_kernel/oCic2NCic.ml +++ b/helm/software/components/ng_kernel/oCic2NCic.ml @@ -1,48 +1,535 @@ -let convert_term = Obj.magic;; +(* + ||M|| This file is part of HELM, an Hypertextual, Electronic + ||A|| Library of Mathematics, developed at the Computer Science + ||T|| Department, University of Bologna, Italy. + ||I|| + ||T|| HELM is free software; you can redistribute it and/or + ||A|| modify it under the terms of the GNU General Public License + \ / version 2 or (at your option) any later version. + \ / This software is distributed as is, NO WARRANTY. + V_______________________________________________________________ *) + +(* $Id$ *) + +module Ref = NReference + +let nuri_of_ouri o = NUri.uri_of_string (UriManager.string_of_uri o);; + +let mk_type n = + if n = 0 then + [false, NUri.uri_of_string ("cic:/matita/pts/Type.univ")] + else + [false, NUri.uri_of_string ("cic:/matita/pts/Type"^string_of_int n^".univ")] +;; + +let mk_cprop n = + if n = 0 then + [false, NUri.uri_of_string ("cic:/matita/pts/CProp.univ")] + else + [false, NUri.uri_of_string ("cic:/matita/pts/CProp"^string_of_int n^".univ")] +;; + +let is_proof_irrelevant context ty = + match + CicReduction.whd context + (fst (CicTypeChecker.type_of_aux' [] context ty CicUniv.oblivion_ugraph)) + with + Cic.Sort Cic.Prop -> true + | Cic.Sort _ -> false + | _ -> assert false +;; + +exception InProp;; + +let get_relevance ty = + let rec aux context ty = + match CicReduction.whd context ty with + Cic.Prod (n,s,t) -> + not (is_proof_irrelevant context s)::aux (Some (n,Cic.Decl s)::context) t + | _ -> [] + in aux [] ty +(* | ty -> if is_proof_irrelevant context ty then raise InProp else [] + in + try aux [] ty + with InProp -> []*) +;; + +(* porcatissima *) +type reference = Ref of NUri.uri * NReference.spec +let reference_of_ouri u indinfo = + let u = nuri_of_ouri u in + NReference.reference_of_string + (NReference.string_of_reference (Obj.magic (Ref (u,indinfo)))) +;; + +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) +;; + +let count_vars vars = + 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) +;; + + +(***** 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) + | ((_,_,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 int * int - let splat mk_pi ctx t = + List.fold_left + (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 osplat 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 _ -> t) + | Some (name, Cic.Def (bo,ty)) -> Cic.LetIn (name, ty, bo, t) + | Some (name, Cic.Decl ty) when mk_pi -> Cic.Prod (name, ty, t) + | Some (name, Cic.Decl ty) -> Cic.Lambda (name, ty, t) + | None -> assert false) t ctx ;; -let splat_args ctx t = - let n_args = - List.length (List.filter (function Ce _ -> true | _ -> false) ctx) - in - if n_args = 0 then t +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 -> + 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 ?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 -> aux (n-1) @ [NCic.Rel n] + | 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 n_args) + let args = aux (List.length ctx,rels) in + match args with + [] -> t + | _::_ -> NCic.Appl (t::args) ;; -let convert_term uri t = - let rec aux octx (ctx : ctx list) n_fix uri = function - | Cic.CoFix (k, fl) -> - let idx = ref ~-1 in - let bctx = - List.map (fun (_,_,_) -> - incr idx; Fix (~-1,!idx)) fl @ ctx - in +let splat_args ctx t n_fix rels = + let bound, _, _, primo_ce_dopo_fix = context_tassonomy ctx in + if ctx = [] then t + else + let rec aux = function + | 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 + let args = aux (List.length ctx,rels) in + match args with + [] -> t + | _::_ -> NCic.Appl (t::args) +;; + +exception Nothing_to_do;; + +let fix_outty curi tyno t context outty = + let leftno,rightno = + match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph curi) with + Cic.InductiveDefinition (tyl,_,leftno,_) -> + let _,_,arity,_ = List.nth tyl tyno in + let rec count_prods leftno context arity = + match leftno, CicReduction.whd context arity with + 0, Cic.Sort _ -> 0 + | 0, Cic.Prod (name,so,ty) -> + 1 + count_prods 0 (Some (name, Cic.Decl so)::context) ty + | _, Cic.Prod (name,so,ty) -> + count_prods (leftno - 1) (Some (name, Cic.Decl so)::context) ty + | _,_ -> assert false + in +(*prerr_endline (UriManager.string_of_uri curi); +prerr_endline ("LEFTNO: " ^ string_of_int leftno ^ " " ^ CicPp.ppterm arity);*) + leftno, count_prods leftno [] arity + | _ -> assert false in + let ens,args = + let tty,_= CicTypeChecker.type_of_aux' [] context t CicUniv.oblivion_ugraph in + match CicReduction.whd context tty with + Cic.MutInd (_,_,ens) -> ens,[] + | Cic.Appl (Cic.MutInd (_,_,ens)::args) -> + ens,fst (HExtlib.split_nth leftno args) + | _ -> assert false + in + let rec aux n irl context outsort = + match n, CicReduction.whd context outsort with + 0, Cic.Prod _ -> raise Nothing_to_do + | 0, _ -> + let irl = List.rev irl in + let ty = CicSubstitution.lift rightno (Cic.MutInd (curi,tyno,ens)) in + let ty = + if args = [] && irl = [] then ty + else + Cic.Appl (ty::(List.map (CicSubstitution.lift rightno) args)@irl) in + let he = CicSubstitution.lift (rightno + 1) outty in + let t = + if irl = [] then he + else Cic.Appl (he::List.map (CicSubstitution.lift 1) irl) + in + Cic.Lambda (Cic.Anonymous, ty, t) + | n, Cic.Prod (name,so,ty) -> + let ty' = + aux (n - 1) (Cic.Rel n::irl) (Some (name, Cic.Decl so)::context) ty + in + Cic.Lambda (name,so,ty') + | _,_ -> assert false + in +(*prerr_endline ("RIGHTNO = " ^ string_of_int rightno ^ " OUTTY = " ^ CicPp.ppterm outty);*) + let outsort = + fst (CicTypeChecker.type_of_aux' [] context outty CicUniv.oblivion_ugraph) + in + try aux rightno [] context outsort + with Nothing_to_do -> outty +(*prerr_endline (CicPp.ppterm outty ^ " <==> " ^ CicPp.ppterm outty');*) +;; + +let fix_outtype t = + let module C = Cic in + let rec aux context = + function + C.Rel _ as t -> t + | C.Var (uri,exp_named_subst) -> + let exp_named_subst' = + List.map (function i,t -> i, (aux context t)) exp_named_subst in + C.Var (uri,exp_named_subst') + | C.Implicit _ + | C.Meta _ -> assert false + | C.Sort _ as t -> t + | C.Cast (v,t) -> C.Cast (aux context v, aux context t) + | C.Prod (n,s,t) -> + C.Prod (n, aux context s, aux ((Some (n, C.Decl s))::context) t) + | C.Lambda (n,s,t) -> + C.Lambda (n, aux context s, aux ((Some (n, C.Decl s))::context) t) + | C.LetIn (n,s,ty,t) -> + C.LetIn + (n, aux context s, aux context ty, + aux ((Some (n, C.Def(s,ty)))::context) t) + | C.Appl l -> C.Appl (List.map (aux context) l) + | C.Const (uri,exp_named_subst) -> + let exp_named_subst' = + List.map (function i,t -> i, (aux context t)) exp_named_subst + in + C.Const (uri,exp_named_subst') + | C.MutInd (uri,tyno,exp_named_subst) -> + let exp_named_subst' = + List.map (function i,t -> i, (aux context t)) exp_named_subst + in + C.MutInd (uri, tyno, exp_named_subst') + | C.MutConstruct (uri,tyno,consno,exp_named_subst) -> + let exp_named_subst' = + List.map (function i,t -> i, (aux context t)) exp_named_subst + in + C.MutConstruct (uri, tyno, consno, exp_named_subst') + | C.MutCase (uri, tyno, outty, term, patterns) -> + let outty = fix_outty uri tyno term context outty in + C.MutCase (uri, tyno, aux context outty, + aux context term, List.map (aux context) patterns) + | C.Fix (funno, funs) -> + let tys,_ = + List.fold_left + (fun (types,len) (n,_,ty,_) -> + ((Some (C.Name n,(C.Decl (CicSubstitution.lift len ty)))))::types, + len+1 + ) ([],0) funs + in + C.Fix (funno, + List.map + (fun (name, indidx, ty, bo) -> + (name, indidx, aux context ty, aux (tys@context) bo) + ) funs + ) + | C.CoFix (funno, funs) -> + let tys,_ = + List.fold_left + (fun (types,len) (n,ty,_) -> + ((Some (C.Name n,(C.Decl (CicSubstitution.lift len ty)))))::types, + len+1 + ) ([],0) funs + in + C.CoFix (funno, + List.map + (fun (name, ty, bo) -> + (name, aux context ty, aux (tys@context) bo) + ) funs + ) + in + 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 (b1,l1,_)), (_,_,_,_,NCic.Fixpoint (b2,l2,_)) + when List.for_all2 (fun (_,_,_,ty1,bo1) (_,_,_,ty2,bo2) -> + alpha ty1 ty2 ref ref' && alpha bo1 bo2 ref ref') l1 l2 && b1=b2-> + 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 + | NReference.Ref (_,NReference.CoFix (fixno)) -> ~-1,fixno + | _ -> assert false in + let recno',fixno' = + match ref' with + NReference.Ref (_,NReference.Fix (fixno',recno,_)) -> recno,fixno' + | NReference.Ref (_,NReference.CoFix (fixno')) -> ~-1,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 (_,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) + | (_,_,_,_,NCic.Fixpoint (false,fl,_)) , + NReference.Ref (_,NReference.CoFix _) -> + ignore(List.fold_left (fun i (_,name,_,_,_) -> + let ref = NReference.mk_cofix i ref in + Hashtbl.add cache name (ref,obj); + i+1 + ) 0 fl) + | _ -> assert false + end; + None + with Found ref -> Some ref +;; + +let cache1 = UriManager.UriHashtbl.create 313;; +let rec get_height = + function u -> + try + UriManager.UriHashtbl.find cache1 u + with + Not_found -> + let h = ref 0 in + let res = + match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph u) with + Cic.Constant (_,Some bo,ty,params,_) + | Cic.Variable (_,Some bo,ty,params,_) -> + ignore (height_of_term ~h bo); + ignore (height_of_term ~h ty); + List.iter (function uri -> h := max !h (get_height uri)) params; + 1 + !h + | _ -> 0 + in + UriManager.UriHashtbl.add cache1 u res; + res +and height_of_term ?(h=ref 0) t = + let rec aux = + function + Cic.Rel _ + | Cic.Sort _ -> () + | Cic.Implicit _ -> assert false + | Cic.Var (uri,exp_named_subst) + | Cic.Const (uri,exp_named_subst) + | Cic.MutInd (uri,_,exp_named_subst) + | Cic.MutConstruct (uri,_,_,exp_named_subst) -> + h := max !h (get_height uri); + List.iter (function (_,t) -> aux t) exp_named_subst + | Cic.Meta (_,l) -> List.iter (function None -> () | Some t -> aux t) l + | Cic.Cast (t1,t2) + | Cic.Prod (_,t1,t2) + | Cic.Lambda (_,t1,t2) -> aux t1; aux t2 + | Cic.LetIn (_,s,ty,t) -> aux s; aux ty; aux t + | Cic.Appl l -> List.iter aux l + | Cic.MutCase (_,_,outty,t,pl) -> aux outty; aux t; List.iter aux pl + | Cic.Fix (_, fl) -> List.iter (fun (_, _, ty, bo) -> aux ty; aux bo) fl; incr h + | Cic.CoFix (_, fl) -> List.iter (fun (_, ty, bo) -> aux ty; aux bo) fl; incr h + in + aux t; + 1 + !h +;; + + (* 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.string_of_uri uri^string_of_int (List.length ctx)^".con") + (UriManager.buri_of_uri uri^"/"^ + UriManager.name_of_uri uri ^ "___" ^ get_fresh () ^ ".con") in + let bctx, fixpoints_tys, tys, _ = + List.fold_right + (fun (name,ty,_) (bctx, fixpoints, tys, idx) -> + let ty, fixpoints_ty = aux true octx ctx n_fix uri ty in + let r = reference_of_ouri buri(Ref.CoFix idx) in + 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 boctx,_ = List.fold_left @@ -51,30 +538,55 @@ let convert_term uri t = len+1)) (octx,0) fl in let fl, fixpoints = - List.fold_right - (fun (name,ty,bo) (l,fixpoints) -> - let ty, fixpoints_ty = aux octx ctx n_fix uri ty in - let bo, fixpoints_bo = aux boctx bctx (n_fix + n_fl) buri bo in - (([],name,~-1,splat true ctx ty, splat false ctx bo)::l), - fixpoints_ty @ fixpoints_bo @ fixpoints) - fl ([],[]) + List.fold_right2 + (fun (name,_,bo) ty (l,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 = - NUri.nuri_of_ouri uri,0,[],[], + nuri_of_ouri buri,0,[],[], NCic.Fixpoint (false, fl, (`Generated, `Definition)) in - NCic.Const (NReference.reference_of_ouri uri (NReference.CoFix (k))), - obj::fixpoints - | Cic.Fix (k, fl) -> - let idx = ref ~-1 in - let rno = ref 0 in - let bctx = - List.map (fun (_,recno,_,_) -> - incr idx; if !idx = k then rno := recno;Fix (recno,!idx)) fl @ ctx + let r = reference_of_ouri buri (Ref.CoFix cofixno) in + let obj,r = + let _,name,_,_,_ = List.nth fl cofixno in + match find_in_cache name obj r with + Some r' -> [],r' + | None -> [obj],r in + splat_args ctx (NCic.Const r) n_fix rels, fixpoints @ obj + | 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.string_of_uri uri^string_of_int (List.length ctx)^".con") + (UriManager.buri_of_uri uri^"/"^ + UriManager.name_of_uri uri ^ "___" ^ get_fresh () ^ ".con") in + let height = height_of_term fix - 1 in + let bad_bctx, fixpoints_tys, tys, _ = + List.fold_right + (fun (name,recno,ty,_) (bctx, fixpoints, tys, idx) -> + 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 *) + reference_of_ouri buri (Ref.Fix (idx,recno,height)) + in + bctx @ [Fix (lazy (r,name,ty))], + fixpoints_ty@fixpoints,ty::tys,idx-1) + fl ([], [], [], List.length fl-1) + in + let _, _, free_decls, _ = context_tassonomy (bad_bctx @ ctx) in + let free_decls = Lazy.force free_decls in + let bctx = + List.map (function ce -> match strictify ce with + | `Fix (Ref.Ref (_,Ref.Fix (idx, recno,height)),name, ty) -> + Fix (lazy (reference_of_ouri buri + (Ref.Fix (idx,recno+free_decls,height)),name,ty)) + | _ -> assert false) bad_bctx @ ctx in let n_fl = List.length fl in let boctx,_ = @@ -83,123 +595,279 @@ let convert_term uri t = (Some (Cic.Name n,(Cic.Decl (CicSubstitution.lift len ty)))::types, len+1)) (octx,0) fl in - let fl, fixpoints = - List.fold_right - (fun (name,rno,ty,bo) (l,fixpoints) -> - let ty, fixpoints_ty = aux octx ctx n_fix uri ty in - let bo, fixpoints_bo = aux boctx bctx (n_fix + n_fl) buri bo in - let rno = rno + List.length ctx - n_fix in - (([],name,rno,splat true ctx ty, splat false ctx bo)::l), - fixpoints_ty @ fixpoints_bo @ fixpoints) - fl ([],[]) + let rno_fixno = ref 0 in + let fl, fixpoints,_ = + List.fold_right2 + (fun (name,rno,oty,bo) ty (l,fixpoints,idx) -> + 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; + ((get_relevance (osplat true octx oty),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 uri,0,[],[], - NCic.Fixpoint (true, fl, (`Generated, `Definition)) + nuri_of_ouri buri,height,[],[], + NCic.Fixpoint (true, fl, (`Generated, `Definition)) in +(*prerr_endline ("H(" ^ UriManager.string_of_uri buri ^ ") = " ^ string_of_int * height);*) + let r = reference_of_ouri buri (Ref.Fix (fixno,!rno_fixno,height)) 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 - NCic.Const (NReference.reference_of_ouri uri (NReference.Fix (k,!rno))), - obj::fixpoints + splat_args ctx (NCic.Const r) n_fix rels, fixpoints @ obj | Cic.Rel n -> - (match List.nth ctx n with - | Ce _ -> NCic.Rel (n-n_fix), [] - | Fix (recno, fixno) -> - splat_args ctx - (NCic.Const - (NReference.reference_of_ouri uri (NReference.Fix (fixno,recno)))), - []) + let bound, _, _, primo_ce_dopo_fix = context_tassonomy ctx in + (match List.nth ctx (n-1) with + | 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 _ 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, (s as old_s), t) -> - let s, fixpoints_s = aux octx ctx n_fix uri s in - let old_ty,_ = - CicTypeChecker.type_of_aux' [] octx old_s CicUniv.oblivion_ugraph - in - let ty, fixpoints_ty = aux octx ctx n_fix uri old_ty in - let ctx = Ce (cn_to_s name, NCic.Def (s, ty)) :: ctx in - let octx = Some (name, Cic.Def (old_s, Some old_ty)) :: octx in - let t, fixpoints_t = aux octx ctx n_fix uri t in - NCic.LetIn (cn_to_s name, ty, s, t), + | Cic.LetIn (name, (te as old_te), (ty as old_ty), t) -> + 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 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.Set -> NCic.Sort NCic.Set,[] - | Cic.Sort Cic.CProp -> NCic.Sort NCic.CProp,[] - | Cic.Sort (Cic.Type _) -> NCic.Sort (NCic.Type 0),[] + | Cic.Sort (Cic.CProp u) -> + NCic.Sort (NCic.Type (mk_cprop (CicUniv.get_rank u))),[] + | Cic.Sort (Cic.Type u) -> + NCic.Sort (NCic.Type (mk_type (CicUniv.get_rank u))),[] + | Cic.Sort Cic.Set -> NCic.Sort (NCic.Type (mk_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 l, fixpoints - | Cic.Const (curi, _) -> - NCic.Const (NReference.reference_of_ouri curi NReference.Def),[] - | Cic.MutInd (curi, tyno, _) -> - NCic.Const (NReference.reference_of_ouri curi (NReference.Ind tyno)),[] - | Cic.MutConstruct (curi, tyno, consno, _) -> - NCic.Const (NReference.reference_of_ouri curi - (NReference.Con (tyno,consno))),[] - | Cic.MutCase (curi, tyno, oty, t, branches) -> - let r = NReference.reference_of_ouri curi (NReference.Ind tyno) in - let oty, fixpoints_oty = aux octx ctx n_fix uri oty in - let t, fixpoints_t = aux octx ctx n_fix uri t in + (match l with + | (NCic.Appl l1)::l2 -> NCic.Appl (l1@l2), fixpoints + | _ -> NCic.Appl l, fixpoints) + | Cic.Const (curi, 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 (reference_of_ouri curi (Ref.Def (get_height curi))) + | Cic.Constant (_,None,_,_,_) -> + NCic.Const (reference_of_ouri curi Ref.Decl) + | _ -> assert false) + | Cic.MutInd (curi, tyno, ens) -> + let is_inductive, lno = + match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph curi) with + Cic.InductiveDefinition ([],vars,lno,_) -> true, lno + count_vars vars + | Cic.InductiveDefinition ((_,b,_,_)::_,vars,lno,_) -> b, lno + count_vars vars + | _ -> assert false + in + aux_ens k curi octx ctx n_fix uri ens + (NCic.Const (reference_of_ouri curi (Ref.Ind (is_inductive,tyno,lno)))) + | Cic.MutConstruct (curi, tyno, consno, ens) -> + let lno = + match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph curi) with + Cic.InductiveDefinition (_,vars,lno,_) -> lno + count_vars vars + | _ -> assert false + in + aux_ens k curi octx ctx n_fix uri ens + (NCic.Const (reference_of_ouri curi (Ref.Con (tyno,consno,lno)))) + | 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 is_inductive,lno = + match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph curi) with + Cic.InductiveDefinition ([],vars,lno,_) -> true, lno + count_vars vars + | Cic.InductiveDefinition ((_,b,_,_)::_,vars,lno,_) -> b, lno + count_vars vars + | _ -> assert false in + let r = reference_of_ouri curi (Ref.Ind (is_inductive,tyno,lno)) 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,oty,t,branches), fixpoints_oty @ fixpoints_t @ fixpoints - | Cic.Implicit _ | Cic.Meta _ | Cic.Var _ -> assert false + NCic.Match (r,outty,t,branches), fixpoints_outty@fixpoints_t@fixpoints + | Cic.Implicit _ | Cic.Meta _ -> assert false + and aux_ens k curi octx ctx n_fix uri ens he = + match ens with + [] -> he,[] + | _::_ -> + let params = + match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph curi) with + Cic.Constant (_,_,_,params,_) + | Cic.InductiveDefinition (_,params,_,_) -> params + | Cic.Variable _ + | Cic.CurrentProof _ -> assert false + in + let ens,objs = + List.fold_right + (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 + match ens with + [] -> he,objs + | _::_ -> NCic.Appl (he::ens),objs +;; + +(* 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 = + aux false [] [] 0 uri t +;; + +let cook mode vars t = + let t = fix_outtype t in + let varsno = List.length vars in + let t = CicSubstitution.lift varsno t in + let rec aux n acc l = + let subst = + snd(List.fold_left (fun (i,res) uri -> i+1,(uri,Cic.Rel i)::res) (1,[]) acc) in - aux [] [] 0 uri t + match l with + [] -> CicSubstitution.subst_vars subst t + | uri::uris -> + let bo,ty = + match fst (CicEnvironment.get_obj CicUniv.oblivion_ugraph uri) with + Cic.Variable (_,bo,ty,_,_) -> + HExtlib.map_option fix_outtype bo, fix_outtype ty + | _ -> assert false in + let ty = CicSubstitution.subst_vars subst ty in + let bo = HExtlib.map_option (CicSubstitution.subst_vars subst) bo in + let id = Cic.Name (UriManager.name_of_uri uri) in + let t = aux (n-1) (uri::acc) uris in + match bo,ty,mode with + None,ty,`Lambda -> Cic.Lambda (id,ty,t) + | None,ty,`Pi -> Cic.Prod (id,ty,t) + | Some bo,ty,_ -> Cic.LetIn (id,bo,ty,t) + in + aux varsno [] vars ;; let convert_obj_aux uri = function - | Cic.Constant (name, None, ty, _, _) -> + | Cic.Constant (name, None, ty, vars, _) -> + let ty = cook `Pi vars ty in let nty, fixpoints = convert_term uri ty in assert(fixpoints = []); - NCic.Constant ([], name, None, nty, (`Provided,`Theorem,`Regular)), + NCic.Constant (get_relevance ty, name, None, nty, (`Provided,`Theorem,`Regular)), fixpoints - | Cic.Constant (name, Some bo, ty, _, _) -> + | Cic.Constant (name, Some bo, ty, vars, _) -> + let bo = cook `Lambda vars bo in + let ty = cook `Pi vars ty in let nbo, fixpoints_bo = convert_term uri bo in let nty, fixpoints_ty = convert_term uri ty in assert(fixpoints_ty = []); - NCic.Constant ([], name, Some nbo, nty, (`Provided,`Theorem,`Regular)), + NCic.Constant (get_relevance ty, name, Some nbo, nty, (`Provided,`Theorem,`Regular)), fixpoints_bo @ fixpoints_ty - | Cic.InductiveDefinition (_,_,_,_) -> assert false (* + | Cic.InductiveDefinition (itl,vars,leftno,_) -> let ind = let _,x,_,_ = List.hd itl in x in - let itl = - List.map - (fun name, _, ty, cl -> - [], name, convert_term ty, - List.map (fun name, ty -> [], name, convert_term ty) cl) - itl + let itl, fix_itl = + List.fold_right + (fun (name, _, ty, cl) (itl,acc) -> + let ty = cook `Pi vars ty in + let nty, fix_ty = convert_term uri ty in + let cl, fix_cl = + List.fold_right + (fun (name, ty) (cl,acc) -> + let ty = cook `Pi vars ty in + let nty, fix_ty = convert_term uri ty in + (get_relevance ty, name, nty)::cl, acc @ fix_ty) + cl ([],[]) + in + (get_relevance ty, name, nty, cl)::itl, fix_ty @ fix_cl @ acc) + itl ([],[]) in - NCic.Inductive (ind, leftno, itl, (`Provided, `Regular)) *) + NCic.Inductive(ind, leftno + count_vars 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,0, [], [], o in - obj, fixpoints + let obj = nuri_of_ouri uri,get_height uri, [], [], o in +(*prerr_endline ("H(" ^ UriManager.string_of_uri uri ^ ") = " ^ string_of_int * (get_height uri));*) + fixpoints @ [obj] +;; + +let clear () = + Hashtbl.clear cache; + UriManager.UriHashtbl.clear cache1 +;; + +(* +let convert_context uri = + let name_of = function Cic.Name s -> s | _ -> "_" in + List.fold_right + (function + | (Some (s, Cic.Decl t) as e) -> fun (nc,auxc,oc) -> + let t, _ = aux true oc auxc 0 uri t in + (name_of s, NCic.Decl t) :: nc, + Ce (lazy ((name_of s, NCic.Decl t),[])) :: auxc, e :: oc + | (Some (Cic.Name s, Cic.Def (t,ty)) as e) -> fun (nc,auxc,oc) -> + let t, _ = aux true oc auxc 0 uri t in + let t, _ = aux true oc auxc 0 uri ty in + (name_of s, NCic.Def (t,ty)) :: nc, + Ce (lazy ((name_of s, NCic.Def (t,ty)),[])) :: auxc, e :: oc + | None -> nc, , e :: oc +;; + +let convert_term uri ctx t = + aux false [] [] 0 uri t ;; +*)