* http://cs.unibo.it/helm/.
*)
-exception ReferenceToVariable;;
-exception RferenceToCurrentProof;;
-exception ReferenceToInductiveDefinition;;
+exception ReferenceToNonVariable;;
+let prerr_endline _ = ();;
+
+(*
+let rec fix_lambdas_wrt_type ty te =
+ let module C = Cic in
+ let module S = CicSubstitution in
+(* prerr_endline ("entering fix_lambdas: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm te); *)
+ match ty with
+ C.Prod (_,_,ty') ->
+ (match CicReduction.whd [] te with
+ C.Lambda (n,s,te') ->
+ C.Lambda (n,s,fix_lambdas_wrt_type ty' te')
+ | t ->
+ let rec get_sources =
+ function
+ C.Prod (_,s,ty) -> s::(get_sources ty)
+ | _ -> [] in
+ let sources = get_sources ty in
+ let no_sources = List.length sources in
+ let rec mk_rels n shift =
+ if n = 0 then []
+ else (C.Rel (n + shift))::(mk_rels (n - 1) shift) in
+ let t' = S.lift no_sources t in
+ let t2 =
+ match t' with
+ C.Appl l ->
+ C.LetIn
+ (C.Name "w",t',C.Appl ((C.Rel 1)::(mk_rels no_sources 1)))
+ | _ ->
+ C.Appl (t'::(mk_rels no_sources 0)) in
+ List.fold_right
+ (fun source t -> C.Lambda (C.Name "y",source,t))
+ sources t2)
+ | _ -> te
+;; *)
+
+let rec fix_lambdas_wrt_type ty te =
+ let module C = Cic in
+ let module S = CicSubstitution in
+(* prerr_endline ("entering fix_lambdas: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm te); *)
+ match ty,te with
+ C.Prod (_,_,ty'), C.Lambda (n,s,te') ->
+ C.Lambda (n,s,fix_lambdas_wrt_type ty' te')
+ | C.Prod (_,s,ty'), t ->
+ let rec get_sources =
+ function
+ C.Prod (_,s,ty) -> s::(get_sources ty)
+ | _ -> [] in
+ let sources = get_sources ty in
+ let no_sources = List.length sources in
+ let rec mk_rels n shift =
+ if n = 0 then []
+ else (C.Rel (n + shift))::(mk_rels (n - 1) shift) in
+ let t' = S.lift no_sources t in
+ let t2 =
+ match t' with
+ C.Appl l ->
+ C.LetIn (C.Name "w",t',C.Appl ((C.Rel 1)::(mk_rels no_sources 1)))
+ | _ -> C.Appl (t'::(mk_rels no_sources 0)) in
+ List.fold_right
+ (fun source t -> C.Lambda (C.Name "y",CicReduction.whd [] source,t)) sources t2
+ | _, _ -> te
+;;
+
+(*
let rec fix_lambdas_wrt_type ty te =
let module C = Cic in
let module S = CicSubstitution in
-(* prerr_endline ("entering fix_lambdas: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm te);
- flush stderr ; *)
- (* cast e altra porcheria ???? *)
+(* prerr_endline ("entering fix_lambdas: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm te); *)
match ty,te with
C.Prod (_,_,ty'), C.Lambda (n,s,te') ->
C.Lambda (n,s,fix_lambdas_wrt_type ty' te')
+ | C.Prod (_,s,ty'), ((C.Appl (C.Const _ ::_)) as t) ->
+ (* const have a fixed arity *)
+ (* prerr_endline ("******** fl - eta expansion 0: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm te); *)
+ let t' = S.lift 1 t in
+ C.Lambda (C.Name "x",s,
+ C.LetIn
+ (C.Name "H", fix_lambdas_wrt_type ty' t',
+ C.Appl [C.Rel 1;C.Rel 2]))
| C.Prod (_,s,ty'), C.Appl l ->
- prerr_endline ("******** fl - eta expansion 1: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm te);
- flush stderr ;
+ (* prerr_endline ("******** fl - eta expansion 1: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm te); *)
let l' = List.map (S.lift 1) l in
C.Lambda (C.Name "x",s,
fix_lambdas_wrt_type ty' (C.Appl (l'@[C.Rel 1])))
| C.Prod (_,s,ty'), _ ->
- prerr_endline ("******** fl - eta expansion 2: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm te);
+ (* prerr_endline ("******** fl - eta expansion 2: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm te); *)
flush stderr ;
let te' = S.lift 1 te in
C.Lambda (C.Name "x",s,
fix_lambdas_wrt_type ty' (C.Appl [te';C.Rel 1]))
| _, _ -> te
-;;
+;;*)
let fix_according_to_type ty hd tl =
let module C = Cic in
let module S = CicSubstitution in
- let rec aux ty tl res =
- (* prerr_endline ("entering aux_1 with type=" ^ CicPp.ppterm ty);
- flush stderr ; *)
- match ty with
- C.Rel _
- | C.Var _
- | C.Meta _
- | C.Sort _
- | C.Implicit ->
+ let rec count_prods =
+ function
+ C.Prod (_,_,t) -> 1 + (count_prods t)
+ | _ -> 0 in
+ let expected_arity = count_prods ty in
+ let rec aux n ty tl res =
+ if n = 0 then
(match tl with
- [] -> C.Appl res
- | _ ->
- prerr_endline ("******* fat - too many args: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm (C.Appl res));
- flush stderr ;
- C.LetIn
- (C.Name "H", C.Appl res, C.Appl (C.Rel 1::(List.map (S.lift 1) tl))))
- | C.Cast (v,t) -> aux v tl res
- | C.Prod (n,s,t) ->
- (match tl with
- [] ->
- prerr_endline ("******* fat - eta expansion: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm (C.Appl res));
- flush stderr ;
- let res' = List.map (S.lift 1) res
- in
+ [] ->
+ (match res with
+ [] -> assert false
+ | [res] -> res
+ | _ -> C.Appl res)
+ | _ ->
+ match res with
+ [] -> assert false
+ | [a] -> C.Appl (a::tl)
+ | _ ->
+ (* prerr_endline ("******* too many args: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm (C.Appl res)); *)
+ C.LetIn
+ (C.Name "H",
+ C.Appl res, C.Appl (C.Rel 1::(List.map (S.lift 1) tl))))
+ else
+ let name,source,target =
+ (match ty with
+ C.Prod (C.Name _ as n,s,t) -> n,s,t
+ | C.Prod (C.Anonymous, s,t) -> C.Name "z",s,t
+ | _ -> (* prods number may only increase for substitution *)
+ assert false) in
+ match tl with
+ [] ->
+ (* prerr_endline ("******* too few args: type=" ^ CicPp.ppterm ty ^ "term=" ^ CicPp.ppterm (C.Appl res)); *)
+ let res' = List.map (S.lift 1) res in
C.Lambda
- (C.Name "x", (* Andrea: to do: generate a fresh name *)
- s,
- aux t [] (res'@[C.Rel 1]))
+ (name, source, aux (n-1) target [] (res'@[C.Rel 1]))
| hd::tl' ->
- let hd' = fix_lambdas_wrt_type s hd
- in
- aux (S.subst hd' t) tl' (res@[hd']))
- | C.Lambda _ -> assert false
- | C.LetIn (n,s,t) -> aux (S.subst s t) tl res
- | C.Appl _
- | C.Const _
- | C.MutInd _
- | C.MutConstruct _
- | C.MutCase _
- | C.Fix _
- | C.CoFix _ -> (* ???? *)
- (match tl with
- [] -> C.Appl res
- | _ -> (* Andrea: to do: generate a fresh name *)
- C.LetIn
- (C.Name "H",
- C.Appl res,
- C.Appl (C.Rel 1::(List.map (S.lift 1) tl))))
- in
- aux ty tl [hd]
+ let hd' = fix_lambdas_wrt_type source hd in
+ (* (prerr_endline ("++++++prima :" ^(CicPp.ppterm hd));
+ prerr_endline ("++++++dopo :" ^(CicPp.ppterm hd'))); *)
+ aux (n-1) (S.subst hd' target) tl' (res@[hd']) in
+ aux expected_arity ty tl [hd]
;;
-let eta_fix metasenv t =
- let rec eta_fix' t =
-(* prerr_endline ("entering aux with: term=" ^ CicPp.ppterm t);
+let eta_fix metasenv context t =
+ let rec eta_fix' context t =
+ (* prerr_endline ("entering aux with: term=" ^ CicPp.ppterm t);
flush stderr ; *)
let module C = Cic in
+ let module S = CicSubstitution in
match t with
C.Rel n -> C.Rel n
| C.Var (uri,exp_named_subst) ->
- let exp_named_subst' =
- List.map
- (function i,t -> i, (eta_fix' t)) exp_named_subst
- in
- C.Var (uri,exp_named_subst')
+ let exp_named_subst' = fix_exp_named_subst context exp_named_subst in
+ C.Var (uri,exp_named_subst')
| C.Meta (n,l) ->
let (_,canonical_context,_) =
List.find (function (m,_,_) -> n = m) metasenv
(fun ct t ->
match (ct, t) with
None, _ -> None
- | _, Some t -> Some (eta_fix' t)
+ | _, Some t -> Some (eta_fix' context t)
| Some _, None -> assert false (* due to typing rules *))
canonical_context l
in
C.Meta (n,l')
| C.Sort s -> C.Sort s
- | C.Implicit -> C.Implicit
- | C.Cast (v,t) -> C.Cast (eta_fix' v, eta_fix' t)
- | C.Prod (n,s,t) -> C.Prod (n, eta_fix' s, eta_fix' t)
- | C.Lambda (n,s,t) -> C.Lambda (n, eta_fix' s, eta_fix' t)
- | C.LetIn (n,s,t) -> C.LetIn (n, eta_fix' s, eta_fix' t)
- | C.Appl l ->
- let l' = List.map eta_fix' l
+ | C.Implicit _ as t -> t
+ | C.Cast (v,t) -> C.Cast (eta_fix' context v, eta_fix' context t)
+ | C.Prod (n,s,t) ->
+ C.Prod
+ (n, eta_fix' context s, eta_fix' ((Some (n,(C.Decl s)))::context) t)
+ | C.Lambda (n,s,t) ->
+ C.Lambda
+ (n, eta_fix' context s, eta_fix' ((Some (n,(C.Decl s)))::context) t)
+ | C.LetIn (n,s,t) ->
+ C.LetIn
+ (n,eta_fix' context s,eta_fix' ((Some (n,(C.Def (s,None))))::context) t)
+ | C.Appl l as appl ->
+ let l' = List.map (eta_fix' context) l
in
(match l' with
+ [] -> assert false
+ | he::tl ->
+ let ty = CicTypeChecker.type_of_aux' metasenv context he in
+ fix_according_to_type ty he tl
+(*
C.Const(uri,exp_named_subst)::l'' ->
let constant_type =
(match CicEnvironment.get_obj uri with
C.Constant (_,_,ty,_) -> ty
| C.Variable _ -> raise ReferenceToVariable
- | C.CurrentProof (_,_,_,_,params) -> raise RferenceToCurrentProof
+ | C.CurrentProof (_,_,_,_,params) -> raise ReferenceToCurrentProof
| C.InductiveDefinition _ -> raise ReferenceToInductiveDefinition
- )
- in
- fix_according_to_type constant_type (C.Const(uri,exp_named_subst)) l''
- | _ -> C.Appl l' )
+ ) in
+ fix_according_to_type
+ constant_type (C.Const(uri,exp_named_subst)) l''
+ | _ -> C.Appl l' *))
| C.Const (uri,exp_named_subst) ->
- let exp_named_subst' =
- List.map
- (function i,t -> i, (eta_fix' t)) exp_named_subst
- in
- C.Const (uri,exp_named_subst')
+ let exp_named_subst' = fix_exp_named_subst context 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, (eta_fix' t)) exp_named_subst
- in
+ let exp_named_subst' = fix_exp_named_subst context 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, (eta_fix' t)) exp_named_subst
- in
+ let exp_named_subst' = fix_exp_named_subst context exp_named_subst in
C.MutConstruct (uri, tyno, consno, exp_named_subst')
- | C.MutCase (uri, tyno, outty, term, patterns) ->
- C.MutCase (uri, tyno, eta_fix' outty,
- eta_fix' term, List.map eta_fix' patterns)
+ | C.MutCase (uri, tyno, outty, term, patterns) as prima ->
+ let outty' = eta_fix' context outty in
+ let term' = eta_fix' context term in
+ let patterns' = List.map (eta_fix' context) patterns in
+ let inductive_types,noparams =
+ (match CicEnvironment.get_obj uri with
+ Cic.Constant _ -> assert false
+ | Cic.Variable _ -> assert false
+ | Cic.CurrentProof _ -> assert false
+ | Cic.InductiveDefinition (l,_,n) -> l,n
+ ) in
+ let (_,_,_,constructors) = List.nth inductive_types tyno in
+ let constructor_types =
+ let rec clean_up t =
+ function
+ [] -> t
+ | a::tl ->
+ (match t with
+ Cic.Prod (_,_,t') -> clean_up (S.subst a t') tl
+ | _ -> assert false) in
+ if noparams = 0 then
+ List.map (fun (_,t) -> t) constructors
+ else
+ let term_type =
+ CicTypeChecker.type_of_aux' metasenv context term
+ in
+ (match term_type with
+ C.Appl (hd::params) ->
+ let rec first_n n l =
+ if n = 0 then []
+ else
+ (match l with
+ a::tl -> a::(first_n (n-1) tl)
+ | _ -> assert false) in
+ List.map
+ (fun (_,t) ->
+ clean_up t (first_n noparams params)) constructors
+ | _ -> prerr_endline ("QUA"); assert false) in
+ let patterns2 =
+ List.map2 fix_lambdas_wrt_type
+ constructor_types patterns in
+ C.MutCase (uri, tyno, outty',term',patterns2)
| C.Fix (funno, funs) ->
+ let fun_types =
+ List.map (fun (n,_,ty,_) -> Some (C.Name n,(Cic.Decl ty))) funs in
C.Fix (funno,
List.map
(fun (name, no, ty, bo) ->
- (name, no, eta_fix' ty, eta_fix' bo)) funs)
+ (name, no, eta_fix' context ty, eta_fix' (fun_types@context) bo))
+ funs)
| C.CoFix (funno, funs) ->
+ let fun_types =
+ List.map (fun (n,ty,_) -> Some (C.Name n,(Cic.Decl ty))) funs in
C.CoFix (funno,
List.map
(fun (name, ty, bo) ->
- (name, eta_fix' ty, eta_fix' bo)) funs)
- in
- eta_fix' t
+ (name, eta_fix' context ty, eta_fix' (fun_types@context) bo)) funs)
+ and fix_exp_named_subst context exp_named_subst =
+ List.rev
+ (List.fold_left
+ (fun newsubst (uri,t) ->
+ let t' = eta_fix' context t in
+ let ty =
+ match CicEnvironment.get_obj uri with
+ Cic.Variable (_,_,ty,_) -> CicSubstitution.subst_vars newsubst ty
+ | _ -> raise ReferenceToNonVariable in
+ let t'' = fix_according_to_type ty t' [] in
+ (uri,t'')::newsubst
+ ) [] exp_named_subst)
+ in
+ eta_fix' context t
;;
-