let args,sort = NCicReduction.split_prods status ~subst:[] [] (-1) ty in
let args = List.rev_map (function name,_ -> mk_id name) args in
let rec_arg = mk_id (fresh_name ()) in
- let p_ty =
+ let mk_prods =
List.fold_right
- (fun name res -> NotationPt.Binder (`Forall,(name,None),res)) args
+ (fun name res -> NotationPt.Binder (`Forall,(name,None),res)) in
+ let p_ty = mk_prods args
(NotationPt.Binder
(`Forall,
(rec_arg,Some (mk_appl (mk_id ind_name :: params @ args))),
NotationPt.Sort outsort)) in
+ let mk_arrs n = mk_prods (HExtlib.mk_list (mk_id "_") n) in
let args = args @ [rec_arg] in
let k_names = List.map (function _,name,_ -> name_of_k name) cl in
+ (*
let final_params =
List.map (function name -> name, None) params @
[p_name,Some p_ty] @
List.map (function name -> name, None) k_names @
List.map (function name -> name, None) args in
+ *)
let cty = mk_appl (p_name :: args) in
let ty = Some cty in
- let branches =
+ let branches_with_args =
List.map
(function (_,name,ty) ->
let _,ty = NCicReduction.split_prods status ~subst:[] [] leftno ty in
let cargs,ty= my_split_prods status ~subst:[] [] (-1) ty in
- let cargs_and_recursive_args =
- List.rev_map
- (function
+ let cargs_recargs_nih =
+ List.fold_left
+ (fun (acc,nih) -> function
_,NCic.Def _ -> assert false
| name,NCic.Decl ty ->
let context,ty = my_split_prods status ~subst:[] [] (-1) ty in
->
let abs = List.rev_map (fun id,_ -> mk_id id) context in
let name = mk_id name in
- name, Some (
+ (name, Some (
List.fold_right
(fun id res ->
NotationPt.Binder (`Lambda,(id,None),res))
k_names @
List.map (fun _ -> NotationPt.Implicit `JustOne)
(List.tl args) @
- [mk_appl (name::abs)])))
- | _ -> mk_id name,None
- ) cargs in
+ [mk_appl (name::abs)]))))::acc, nih + 1
+ | _ -> (mk_id name,None)::acc,nih
+ ) ([],0) cargs in
+ let cargs_and_recursive_args, nih = cargs_recargs_nih in
let cargs,recursive_args = List.split cargs_and_recursive_args in
let recursive_args = HExtlib.filter_map (fun x -> x) recursive_args in
- NotationPt.Pattern (name,None,List.map (fun x -> x,None) cargs),
- mk_appl (name_of_k name :: cargs @ recursive_args)
+ (NotationPt.Pattern (name,None,List.map (fun x -> x,None) cargs),
+ mk_appl (name_of_k name :: cargs @ recursive_args)), (name,cargs, nih)
) cl
in
- let bo = NotationPt.Case (rec_arg,Some (ind_name,None),None,branches) in
+ let branches, branch_args = List.split branches_with_args in
+ let bo = NotationPt.Case (rec_arg,Some (ind_name,None),Some p_name,branches) in
+ let final_params =
+ List.map (function name -> name, None) params @
+ [p_name,Some p_ty] @
+ List.map (function name, cargs, nih ->
+ name_of_k name,
+ Some (mk_prods cargs (mk_arrs nih
+ (mk_appl
+ (p_name::HExtlib.mk_list (NotationPt.Implicit `JustOne)
+ (List.length args - 1) @
+ [mk_appl (mk_id name :: params @ cargs)]))))) branch_args @
+ List.map (function name -> name, None) args in
let recno = List.length final_params in
let where = recno - 1 in
+ let attrs = `Generated, `Definition, pragma in
let res =
NotationPt.LetRec (`Inductive,
- [final_params, (rec_name,ty), bo, where], rec_name)
+ [final_params, (rec_name,ty), bo, where], attrs)
in
(*
prerr_endline
(function x::_ -> x | _ -> assert false) 80
(NotationPres.mpres_of_box boxml)));
*)
- NotationPt.Theorem
- (`Definition,srec_name,
- NotationPt.Implicit `JustOne,Some res,pragma)
+ res
;;
let ast_of_sort s =
let rec pp rels =
function
NCic.Rel i -> List.nth rels (i - 1)
- | NCic.Const _ as t ->
- NotationPt.Ident
- (status#ppterm ~metasenv:[] ~subst:[] ~context:[] t,None)
+ | NCic.Const _ as t -> NotationPt.NCic t
| NCic.Sort s -> NotationPt.Sort (fst (ast_of_sort s))
| NCic.Meta _
| NCic.Implicit _ -> assert false
| NCic.Lambda (n,s,t) ->
let n = mk_id n in
NotationPt.Binder (`Lambda, (n,Some (pp rels s)), pp (n::rels) t)
- | NCic.LetIn (n,s,ty,t) ->
+ | NCic.LetIn (n,ty,s,t) ->
let n = mk_id n in
NotationPt.LetIn ((n, Some (pp rels ty)), pp rels s, pp (n::rels) t)
| NCic.Match (NReference.Ref (uri,_) as r,outty,te,patterns) ->
in
let params,bo = aux [] consty leftno in
let pprojname = mk_id projname in
+ let attrs = `Generated, `Definition, `Projection in
let res =
NotationPt.LetRec (`Inductive,
- [params, (pprojname,None), bo, leftno], pprojname) in
+ [params, (pprojname,None), bo, leftno], attrs) in
(* prerr_endline
(BoxPp.render_to_string
~map_unicode_to_tex:false
(function x::_ -> x | _ -> assert false)
80 (NotationPres.render (fun _ -> None)
(TermContentPres.pp_ast res)));*)
- NotationPt.Theorem
- (`Definition,projname,NotationPt.Implicit `JustOne,Some res,`Projection)
+ res
;;
let mk_projections status (_,_,_,_,obj) =