(*
type interpretation_id = int
-let idref id t = Ast.AttributedTerm (`IdRef id, t)
-
type term_info =
{ sort: (Cic.id, Ast.sort_kind) Hashtbl.t;
uri: (Cic.id, UriManager.uri) Hashtbl.t;
let get_types uri =
let o,_ = CicEnvironment.get_obj CicUniv.oblivion_ugraph uri in
match o with
- | Cic.InductiveDefinition (l,_,lpsno,_) -> l, lpsno
+ | Cic.InductiveDefinition (l,_,leftno,_) -> l, leftno
| _ -> assert false
-
-let name_of_inductive_type uri i =
- let types, _ = get_types uri in
- let (name, _, _, _) = try List.nth types i with Not_found -> assert false in
- name
-
- (* returns <name, type> pairs *)
-let constructors_of_inductive_type uri i =
- let types, _ = get_types uri in
- let (_, _, _, constructors) =
- try List.nth types i with Not_found -> assert false
- in
- constructors
-
- (* returns name only *)
-let constructor_of_inductive_type uri i j =
- (try
- fst (List.nth (constructors_of_inductive_type uri i) (j-1))
- with Not_found -> assert false)
-
- (* returns the number of left parameters *)
-let left_params_no_of_inductive_type uri =
- snd (get_types uri)
*)
+let idref () =
+ let id = ref 0 in
+ function t ->
+ incr id;
+ Ast.AttributedTerm (`IdRef ("i" ^ string_of_int !id), t)
+;;
+
(* CODICE c&p da NCicPp *)
-let nast_of_cic ~subst ~context =
+let nast_of_cic ~idref ~output_type ~subst ~context =
let rec k ctx = function
| NCic.Rel n ->
(try
let name,_ = List.nth ctx (n-1) in
let name = if name = "_" then "__"^string_of_int n else name in
- Ast.Ident (name,None)
+ idref (Ast.Ident (name,None))
with Failure "nth" | Invalid_argument "List.nth" ->
- Ast.Ident ("-" ^ string_of_int (n - List.length ctx),None))
- | NCic.Const r -> Ast.Ident (NCicPp.r2s false r, None)
+ idref (Ast.Ident ("-" ^ string_of_int (n - List.length ctx),None)))
+ | NCic.Const r -> idref (Ast.Ident (NCicPp.r2s true r, None))
| NCic.Meta (n,lc) when List.mem_assoc n subst ->
let _,_,t,_ = List.assoc n subst in
k ctx (NCicSubstitution.subst_meta lc t)
| NCic.Meta (n,(s,l)) ->
(* CSC: qua non dovremmo espandere *)
let l = NCicUtils.expand_local_context l in
- Ast.Meta
- (n, List.map (fun x -> Some (k ctx (NCicSubstitution.lift s x))) l)
- | NCic.Sort NCic.Prop -> Ast.Sort `Prop
- | NCic.Sort NCic.Type _ -> Ast.Sort `Set
+ idref (Ast.Meta
+ (n, List.map (fun x -> Some (k ctx (NCicSubstitution.lift s x))) l))
+ | NCic.Sort NCic.Prop -> idref (Ast.Sort `Prop)
+ | NCic.Sort NCic.Type _ -> idref (Ast.Sort `Set)
(* CSC: | C.Sort (C.Type []) -> F.fprintf f "Type0"
| C.Sort (C.Type [false, u]) -> F.fprintf f "%s" (NUri.name_of_uri u)
| C.Sort (C.Type [true, u]) -> F.fprintf f "S(%s)" (NUri.name_of_uri u)
(List.tl l);
F.fprintf f ")"*)
(* CSC: qua siamo grezzi *)
- | NCic.Implicit `Hole -> Ast.UserInput
- | NCic.Implicit _ -> Ast.Implicit
+ | NCic.Implicit `Hole -> idref (Ast.UserInput)
+ | NCic.Implicit _ -> idref (Ast.Implicit)
| NCic.Prod (n,s,t) ->
let binder_kind = `Forall in
- Ast.Binder (binder_kind, (Ast.Ident (n,None), Some (k ctx s)),
- k ((n,NCic.Decl s)::ctx) t)
+ idref (Ast.Binder (binder_kind, (Ast.Ident (n,None), Some (k ctx s)),
+ k ((n,NCic.Decl s)::ctx) t))
| NCic.Lambda (n,s,t) ->
- Ast.Binder (`Lambda,(Ast.Ident (n,None), Some (k ctx s)),
- k ((n,NCic.Decl s)::ctx) t)
+ idref (Ast.Binder (`Lambda,(Ast.Ident (n,None), Some (k ctx s)),
+ k ((n,NCic.Decl s)::ctx) t))
| NCic.LetIn (n,s,ty,t) ->
- Ast.LetIn ((Ast.Ident (n,None), Some (k ctx ty)), k ctx s,
- k ((n,NCic.Decl s)::ctx) t)
+ idref (Ast.LetIn ((Ast.Ident (n,None), Some (k ctx ty)), k ctx s,
+ k ((n,NCic.Decl s)::ctx) t))
| NCic.Appl (NCic.Meta (n,lc) :: args) when List.mem_assoc n subst ->
let _,_,t,_ = List.assoc n subst in
let hd = NCicSubstitution.subst_meta lc t in
(match hd with
| NCic.Appl l -> NCic.Appl (l@args)
| _ -> NCic.Appl (hd :: args)))
- | NCic.Appl args -> Ast.Appl (List.map (k ctx) args)
- | NCic.Match (uri,ty,te,patterns) ->
-(*
- let name = NReference.name_of_reference uri in
+ | NCic.Appl args -> idref (Ast.Appl (List.map (k ctx) args))
+ | NCic.Match (NReference.Ref (uri,_) as r,outty,te,patterns) ->
+ let name = NUri.name_of_uri uri in
+(* CSC
let uri_str = UriManager.string_of_uri uri in
let puri_str = sprintf "%s#xpointer(1/%d)" uri_str (typeno+1) in
let ctor_puri j =
UriManager.uri_of_string
(sprintf "%s#xpointer(1/%d/%d)" uri_str (typeno+1) j)
in
- let case_indty = name, Some (UriManager.uri_of_string puri_str) in
- let constructors = constructors_of_inductive_type uri typeno in
- let lpsno = left_params_no_of_inductive_type uri in
- let rec eat_branch n ty pat =
+*)
+ let case_indty =
+ name, None(*CSC Some (UriManager.uri_of_string puri_str)*) in
+ let constructors, leftno =
+ let _,leftno,tys,_,n = NCicEnvironment.get_checked_indtys r in
+ let _,_,_,cl = List.nth tys n in
+ cl,leftno
+ in
+ let rec eat_branch n ctx ty pat =
match (ty, pat) with
- | NCic.Prod (_, _, t), _ when n > 0 -> eat_branch (pred n) t pat
- | NCic.Prod (_, _, t), NCic.ALambda (_, name, s, t') ->
- let (cv, rhs) = eat_branch 0 t t' in
- (CicNotationUtil.name_of_cic_name name, Some (k s)) :: cv, rhs
- | _, _ -> [], k pat
+ | NCic.Prod (name, s, t), _ when n > 0 ->
+ eat_branch (pred n) ((name,NCic.Decl s)::ctx) t pat
+ | NCic.Prod (_, _, t), NCic.Lambda (name, s, t') ->
+ let cv, rhs = eat_branch 0 ((name,NCic.Decl s)::ctx) t t' in
+ (Ast.Ident (name,None), Some (k ctx s)) :: cv, rhs
+ | _, _ -> [], k ctx pat
in
let j = ref 0 in
let patterns =
try
List.map2
- (fun (name, ty) pat ->
+ (fun (_, name, ty) pat ->
incr j;
let name,(capture_variables,rhs) =
match output_type with
- `Term -> name, eat_branch lpsno ty pat
- | `Pattern -> "_", ([], k pat)
+ `Term -> name, eat_branch leftno ctx ty pat
+ | `Pattern -> "_", ([], k ctx pat)
in
- Ast.Pattern (name, Some (ctor_puri !j), capture_variables), rhs
+ Ast.Pattern (name, None(*CSC Some (ctor_puri !j)*), capture_variables), rhs
) constructors patterns
with Invalid_argument _ -> assert false
in
`Pattern -> None
| `Term -> Some case_indty
in
- idref id (Ast.Case (k te, indty, Some (k ty), patterns))
-*) assert false
+ idref (Ast.Case (k ctx te, indty, Some (k ctx outty), patterns))
in
k context
;;
let nmap_sequent ~subst (i,(n,context,ty):int * NCic.conjecture) =
let module K = Content in
+ let nast_of_cic = nast_of_cic ~idref:(idref ()) ~output_type:`Term ~subst in
let context',_ =
List.fold_right
(fun item (res,context) ->
K.dec_id = "-1";
K.dec_inductive = false;
K.dec_aref = "-1";
- K.dec_type = nast_of_cic ~subst ~context t
+ K.dec_type = nast_of_cic ~context t
})::res,item::context
| name,NCic.Def (t,ty) ->
Some
{ K.def_name = (Some name);
K.def_id = "-1";
K.def_aref = "-1";
- K.def_term = nast_of_cic ~subst ~context t;
- K.def_type = nast_of_cic ~subst ~context ty
+ K.def_term = nast_of_cic ~context t;
+ K.def_type = nast_of_cic ~context ty
})::res,item::context
) context ([],[])
in
- "-1",i,context',nast_of_cic ~subst ~context ty
+ "-1",i,context',nast_of_cic ~context ty
;;
(*