--- /dev/null	Thu Jan 01 00:00:00 1970 +0000
+++ b/Nominal/Parser.thy	Fri May 14 18:12:07 2010 +0100
@@ -0,0 +1,706 @@
+theory NewParser
+imports "../Nominal-General/Nominal2_Base" 
+        "../Nominal-General/Nominal2_Eqvt" 
+        "../Nominal-General/Nominal2_Supp" 
+        "Perm" "NewFv" "NewAlpha" "Tacs" "Equivp" "Lift"
+begin
+
+section{* Interface for nominal_datatype *}
+
+
+ML {* 
+(* nominal datatype parser *)
+local
+  structure P = OuterParse;
+  structure S = Scan
+
+  fun triple1 ((x, y), z) = (x, y, z)
+  fun triple2 (x, (y, z)) = (x, y, z)
+  fun tuple ((x, y, z), u) = (x, y, z, u)
+  fun tswap (((x, y), z), u) = (x, y, u, z)
+in
+
+val _ = OuterKeyword.keyword "bind"
+val _ = OuterKeyword.keyword "bind_set"
+val _ = OuterKeyword.keyword "bind_res"
+
+val anno_typ = S.option (P.name --| P.$$$ "::") -- P.typ
+
+val bind_mode = P.$$$ "bind" || P.$$$ "bind_set" || P.$$$ "bind_res"
+
+val bind_clauses = 
+  P.enum "," (bind_mode -- S.repeat1 P.term -- (P.$$$ "in" |-- S.repeat1 P.name) >> triple1)
+
+val cnstr_parser =
+  P.binding -- S.repeat anno_typ -- bind_clauses -- P.opt_mixfix >> tswap
+
+(* datatype parser *)
+val dt_parser =
+  (P.type_args -- P.binding -- P.opt_mixfix >> triple1) -- 
+    (P.$$$ "=" |-- P.enum1 "|" cnstr_parser) >> tuple
+
+(* binding function parser *)
+val bnfun_parser = 
+  S.optional (P.$$$ "binder" |-- P.fixes -- SpecParse.where_alt_specs) ([], [])
+
+(* main parser *)
+val main_parser =
+  P.and_list1 dt_parser -- bnfun_parser >> triple2
+
+end
+*}
+
+ML {*
+fun get_cnstrs dts =
+  map (fn (_, _, _, constrs) => constrs) dts
+
+fun get_typed_cnstrs dts =
+  flat (map (fn (_, bn, _, constrs) => 
+   (map (fn (bn', _, _) => (Binding.name_of bn, Binding.name_of bn')) constrs)) dts)
+
+fun get_cnstr_strs dts =
+  map (fn (bn, _, _) => Binding.name_of bn) (flat (get_cnstrs dts))
+
+fun get_bn_fun_strs bn_funs =
+  map (fn (bn_fun, _, _) => Binding.name_of bn_fun) bn_funs
+*}
+
+
+ML {* 
+fun add_primrec_wrapper funs eqs lthy = 
+  if null funs then (([], []), lthy)
+  else 
+   let 
+     val eqs' = map (fn (_, eq) => (Attrib.empty_binding, eq)) eqs
+     val funs' = map (fn (bn, ty, mx) => (bn, SOME ty, mx)) funs
+     val ((funs'', eqs''), lthy') = Primrec.add_primrec funs' eqs' lthy
+     val phi = ProofContext.export_morphism lthy' lthy
+   in 
+     ((map (Morphism.term phi) funs'', map (Morphism.thm phi) eqs''), lthy')
+   end
+*}
+
+ML {*
+fun add_datatype_wrapper dt_names dts =
+let
+  val conf = Datatype.default_config
+in
+  Local_Theory.theory_result (Datatype.add_datatype conf dt_names dts)
+end
+*}
+
+
+text {* Infrastructure for adding "_raw" to types and terms *}
+
+ML {*
+fun add_raw s = s ^ "_raw"
+fun add_raws ss = map add_raw ss
+fun raw_bind bn = Binding.suffix_name "_raw" bn
+
+fun replace_str ss s = 
+  case (AList.lookup (op=) ss s) of 
+     SOME s' => s'
+   | NONE => s
+
+fun replace_typ ty_ss (Type (a, Ts)) = Type (replace_str ty_ss a, map (replace_typ ty_ss) Ts)
+  | replace_typ ty_ss T = T  
+
+fun raw_dts ty_ss dts =
+let
+  fun raw_dts_aux1 (bind, tys, mx) =
+    (raw_bind bind, map (replace_typ ty_ss) tys, mx)
+
+  fun raw_dts_aux2 (ty_args, bind, mx, constrs) =
+    (ty_args, raw_bind bind, mx, map raw_dts_aux1 constrs)
+in
+  map raw_dts_aux2 dts
+end
+
+fun replace_aterm trm_ss (Const (a, T)) = Const (replace_str trm_ss a, T)
+  | replace_aterm trm_ss (Free (a, T)) = Free (replace_str trm_ss a, T)
+  | replace_aterm trm_ss trm = trm
+
+fun replace_term trm_ss ty_ss trm =
+  trm |> Term.map_aterms (replace_aterm trm_ss) |> map_types (replace_typ ty_ss) 
+*}
+
+ML {*
+fun rawify_dts dt_names dts dts_env =
+let
+  val raw_dts = raw_dts dts_env dts
+  val raw_dt_names = add_raws dt_names
+in
+  (raw_dt_names, raw_dts)
+end 
+*}
+
+ML {*
+fun rawify_bn_funs dts_env cnstrs_env bn_fun_env bn_funs bn_eqs =
+let
+  val bn_funs' = map (fn (bn, ty, mx) => 
+    (raw_bind bn, replace_typ dts_env ty, mx)) bn_funs
+  
+  val bn_eqs' = map (fn (attr, trm) => 
+    (attr, replace_term (cnstrs_env @ bn_fun_env) dts_env trm)) bn_eqs
+in
+  (bn_funs', bn_eqs') 
+end 
+*}
+
+ML {* 
+fun rawify_bclauses dts_env cnstrs_env bn_fun_env bclauses =
+let
+  fun rawify_bnds bnds = 
+    map (apfst (Option.map (replace_term (cnstrs_env @ bn_fun_env) dts_env))) bnds
+
+  fun rawify_bclause (BEmy n) = BEmy n
+    | rawify_bclause (BLst (bnds, bdys)) = BLst (rawify_bnds bnds, bdys)
+    | rawify_bclause (BSet (bnds, bdys)) = BSet (rawify_bnds bnds, bdys)
+    | rawify_bclause (BRes (bnds, bdys)) = BRes (rawify_bnds bnds, bdys)
+in
+  map (map (map rawify_bclause)) bclauses
+end
+*}
+
+(* strip_bn_fun takes a bn function defined by the user as a union or
+   append of elements and returns those elements together with bn functions
+   applied *)
+ML {*
+fun strip_bn_fun t =
+  case t of
+    Const (@{const_name sup}, _) $ l $ r => strip_bn_fun l @ strip_bn_fun r
+  | Const (@{const_name append}, _) $ l $ r => strip_bn_fun l @ strip_bn_fun r
+  | Const (@{const_name insert}, _) $ (Const (@{const_name atom}, _) $ Bound i) $ y =>
+      (i, NONE) :: strip_bn_fun y
+  | Const (@{const_name Cons}, _) $ (Const (@{const_name atom}, _) $ Bound i) $ y =>
+      (i, NONE) :: strip_bn_fun y
+  | Const (@{const_name bot}, _) => []
+  | Const (@{const_name Nil}, _) => []
+  | (f as Free _) $ Bound i => [(i, SOME f)]
+  | _ => error ("Unsupported binding function: " ^ (PolyML.makestring t))
+*}
+
+ML {*
+fun find [] _ = error ("cannot find element")
+  | find ((x, z)::xs) y = if (Long_Name.base_name x) = y then z else find xs y
+*}
+
+ML {*
+fun prep_bn lthy dt_names dts eqs = 
+let
+  fun aux eq = 
+  let
+    val (lhs, rhs) = eq
+      |> strip_qnt_body "all" 
+      |> HOLogic.dest_Trueprop
+      |> HOLogic.dest_eq
+    val (bn_fun, [cnstr]) = strip_comb lhs
+    val (_, ty) = dest_Free bn_fun
+    val (ty_name, _) = dest_Type (domain_type ty)
+    val dt_index = find_index (fn x => x = ty_name) dt_names
+    val (cnstr_head, cnstr_args) = strip_comb cnstr
+    val rhs_elements = strip_bn_fun rhs
+    val included = map (apfst (fn i => length (cnstr_args) - i - 1)) rhs_elements
+  in
+    (dt_index, (bn_fun, (cnstr_head, included)))
+  end
+  fun aux2 eq = 
+  let
+    val (lhs, rhs) = eq
+      |> strip_qnt_body "all" 
+      |> HOLogic.dest_Trueprop
+      |> HOLogic.dest_eq
+    val (bn_fun, [cnstr]) = strip_comb lhs
+    val (_, ty) = dest_Free bn_fun
+    val (ty_name, _) = dest_Type (domain_type ty)
+    val dt_index = find_index (fn x => x = ty_name) dt_names
+    val (cnstr_head, cnstr_args) = strip_comb cnstr
+    val rhs_elements = strip_bn_fun rhs
+    val included = map (apfst (fn i => length (cnstr_args) - i - 1)) rhs_elements
+  in
+    (bn_fun, dt_index, (cnstr_head, included))
+  end 
+  fun order dts i ts = 
+  let
+    val dt = nth dts i
+    val cts = map (fn (x, _, _) => Binding.name_of x) ((fn (_, _, _, x) => x) dt)
+    val ts' = map (fn (x, y) => (fst (dest_Const x), y)) ts
+  in
+    map (find ts') cts
+  end
+
+  val unordered = AList.group (op=) (map aux eqs)
+  val unordered' = map (fn (x, y) =>  (x, AList.group (op=) y)) unordered
+  val ordered = map (fn (x, y) => (x, map (fn (v, z) => (v, order dts x z)) y)) unordered' 
+  val ordered' = flat (map (fn (ith, l) => map (fn (bn, data) => (bn, ith, data)) l) ordered)
+
+  val _ = tracing ("eqs\n" ^ cat_lines (map (Syntax.string_of_term lthy) eqs))
+  val _ = tracing ("map eqs\n" ^ @{make_string} (map aux2 eqs))
+  val _ = tracing ("ordered'\n" ^ @{make_string} ordered')
+in
+  ordered'
+end
+*}
+
+
+ML {*
+fun raw_nominal_decls dts bn_funs bn_eqs binds lthy =
+let
+  val thy = ProofContext.theory_of lthy
+  val thy_name = Context.theory_name thy
+
+  val dt_names = map (fn (_, s, _, _) => Binding.name_of s) dts
+  val dt_full_names = map (Long_Name.qualify thy_name) dt_names 
+  val dt_full_names' = add_raws dt_full_names
+  val dts_env = dt_full_names ~~ dt_full_names'
+
+  val cnstrs = get_cnstr_strs dts
+  val cnstrs_ty = get_typed_cnstrs dts
+  val cnstrs_full_names = map (Long_Name.qualify thy_name) cnstrs
+  val cnstrs_full_names' = map (fn (x, y) => Long_Name.qualify thy_name 
+    (Long_Name.qualify (add_raw x) (add_raw y))) cnstrs_ty
+  val cnstrs_env = cnstrs_full_names ~~ cnstrs_full_names'
+
+  val bn_fun_strs = get_bn_fun_strs bn_funs
+  val bn_fun_strs' = add_raws bn_fun_strs
+  val bn_fun_env = bn_fun_strs ~~ bn_fun_strs'
+  val bn_fun_full_env = map (pairself (Long_Name.qualify thy_name)) 
+    (bn_fun_strs ~~ bn_fun_strs')
+  
+  val (raw_dt_names, raw_dts) = rawify_dts dt_names dts dts_env
+
+  val (raw_bn_funs, raw_bn_eqs) = rawify_bn_funs dts_env cnstrs_env bn_fun_env bn_funs bn_eqs 
+   
+  val raw_bclauses = rawify_bclauses dts_env cnstrs_env bn_fun_full_env binds 
+
+  val raw_bns = prep_bn lthy dt_full_names' raw_dts (map snd raw_bn_eqs)
+in
+  lthy 
+  |> add_datatype_wrapper raw_dt_names raw_dts 
+  ||>> add_primrec_wrapper raw_bn_funs raw_bn_eqs
+  ||>> pair raw_bclauses
+  ||>> pair raw_bns
+end
+*}
+
+lemma equivp_hack: "equivp x"
+sorry
+ML {*
+fun equivp_hack ctxt rel =
+let
+  val thy = ProofContext.theory_of ctxt
+  val ty = domain_type (fastype_of rel)
+  val cty = ctyp_of thy ty
+  val ct = cterm_of thy rel
+in
+  Drule.instantiate' [SOME cty] [SOME ct] @{thm equivp_hack}
+end
+*}
+
+ML {* val cheat_equivp = Unsynchronized.ref false *}
+ML {* val cheat_fv_rsp = Unsynchronized.ref false *}
+ML {* val cheat_alpha_bn_rsp = Unsynchronized.ref false *}
+ML {* val cheat_supp_eq = Unsynchronized.ref false *}
+
+ML {*
+fun remove_loop t =
+  let val _ = HOLogic.dest_eq (HOLogic.dest_Trueprop (prop_of t)) in t end
+  handle TERM _ => @{thm eqTrueI} OF [t]
+*}
+
+text {* 
+  nominal_datatype2 does the following things in order:
+
+Parser.thy/raw_nominal_decls
+  1) define the raw datatype
+  2) define the raw binding functions 
+
+Perm.thy/define_raw_perms
+  3) define permutations of the raw datatype and show that the raw type is 
+     in the pt typeclass
+      
+Lift.thy/define_fv_alpha_export, Fv.thy/define_fv & define_alpha
+  4) define fv and fv_bn
+  5) define alpha and alpha_bn
+
+Perm.thy/distinct_rel
+  6) prove alpha_distincts (C1 x \<notsimeq> C2 y ...)             (Proof by cases; simp)
+
+Tacs.thy/build_rel_inj
+  6) prove alpha_eq_iff    (C1 x = C2 y \<leftrightarrow> P x y ...)
+     (left-to-right by intro rule, right-to-left by cases; simp)
+Equivp.thy/prove_eqvt
+  7) prove bn_eqvt (common induction on the raw datatype)
+  8) prove fv_eqvt (common induction on the raw datatype with help of above)
+Rsp.thy/build_alpha_eqvts
+  9) prove alpha_eqvt and alpha_bn_eqvt
+     (common alpha-induction, unfolding alpha_gen, permute of #* and =)
+Equivp.thy/build_alpha_refl & Equivp.thy/build_equivps
+ 10) prove that alpha and alpha_bn are equivalence relations
+     (common induction and application of 'compose' lemmas)
+Lift.thy/define_quotient_types
+ 11) define quotient types
+Rsp.thy/build_fvbv_rsps
+ 12) prove bn respects     (common induction and simp with alpha_gen)
+Rsp.thy/prove_const_rsp
+ 13) prove fv respects     (common induction and simp with alpha_gen)
+ 14) prove permute respects    (unfolds to alpha_eqvt)
+Rsp.thy/prove_alpha_bn_rsp
+ 15) prove alpha_bn respects
+     (alpha_induct then cases then sym and trans of the relations)
+Rsp.thy/prove_alpha_alphabn
+ 16) show that alpha implies alpha_bn (by unduction, needed in following step)
+Rsp.thy/prove_const_rsp
+ 17) prove respects for all datatype constructors
+     (unfold eq_iff and alpha_gen; introduce zero permutations; simp)
+Perm.thy/quotient_lift_consts_export
+ 18) define lifted constructors, fv, bn, alpha_bn, permutations
+Perm.thy/define_lifted_perms
+ 19) lift permutation zero and add properties to show that quotient type is in the pt typeclass
+Lift.thy/lift_thm
+ 20) lift permutation simplifications
+ 21) lift induction
+ 22) lift fv
+ 23) lift bn
+ 24) lift eq_iff
+ 25) lift alpha_distincts
+ 26) lift fv and bn eqvts
+Equivp.thy/prove_supports
+ 27) prove that union of arguments supports constructors
+Equivp.thy/prove_fs
+ 28) show that the lifted type is in fs typeclass     (* by q_induct, supports *)
+Equivp.thy/supp_eq
+ 29) prove supp = fv
+*}
+
+ML {*
+(* for testing porposes - to exit the procedure early *)
+exception TEST of Proof.context
+
+val (STEPS, STEPS_setup) = Attrib.config_int "STEPS" (K 10);
+
+fun get_STEPS ctxt = Config.get ctxt STEPS
+*}
+
+setup STEPS_setup
+
+
+ML {*
+fun nominal_datatype2 dts bn_funs bn_eqs bclauses lthy =
+let
+  (* definition of the raw datatype and raw bn-functions *)
+  val ((((raw_dt_names, (raw_bn_funs, raw_bn_eqs)), raw_bclauses), raw_bns), lthy1) =
+    if get_STEPS lthy > 1 then raw_nominal_decls dts bn_funs bn_eqs bclauses lthy
+    else raise TEST lthy
+
+  val dtinfo = Datatype.the_info (ProofContext.theory_of lthy1) (hd raw_dt_names);
+  val {descr, sorts, ...} = dtinfo;
+  val raw_tys = map (fn (i, _) => nth_dtyp descr sorts i) descr;
+
+  val induct_thm = #induct dtinfo;
+
+  (* definitions of raw permutations *)
+  val ((raw_perm_def, raw_perm_simps, perms), lthy2) =
+    if get_STEPS lthy > 2 
+    then Local_Theory.theory_result (define_raw_perms descr sorts induct_thm (length dts)) lthy1
+    else raise TEST lthy1
+
+  (* definition of raw fv_functions *)
+  val morphism_2_0 = ProofContext.export_morphism lthy2 lthy
+  fun export_fun f (t, n , l) = (f t, n, map (map (apsnd (Option.map f))) l);
+  val bn_funs_decls = map (export_fun (Morphism.term morphism_2_0)) raw_bns;
+ 
+  val thy = Local_Theory.exit_global lthy2;
+  val thy_name = Context.theory_name thy
+
+  val lthy3 = Theory_Target.init NONE thy;
+  val raw_bn_funs = map (fn (f, _, _) => f) bn_funs_decls;
+
+  val _ = tracing ("raw_bns\n" ^ @{make_string} raw_bns)
+  val _ = tracing ("bn_funs\n" ^ @{make_string} bn_funs_decls)
+   
+  val ((fv, fvbn), fv_def, lthy3a) = 
+    if get_STEPS lthy > 3 
+    then define_raw_fv descr sorts bn_funs_decls raw_bclauses lthy3
+    else raise TEST lthy3
+  
+in
+  (0, lthy3a)
+end handle TEST ctxt => (0, ctxt)
+*}
+
+section {* Preparing and parsing of the specification *}
+
+ML {* 
+(* parsing the datatypes and declaring *)
+(* constructors in the local theory    *)
+fun prepare_dts dt_strs lthy = 
+let
+  val thy = ProofContext.theory_of lthy
+  
+  fun mk_type full_tname tvrs =
+    Type (full_tname, map (fn a => TVar ((a, 0), [])) tvrs)
+
+  fun prep_cnstr full_tname tvs (cname, anno_tys, mx, _) =
+  let
+    val tys = map (Syntax.read_typ lthy o snd) anno_tys
+    val ty = mk_type full_tname tvs
+  in
+    ((cname, tys ---> ty, mx), (cname, tys, mx))
+  end
+  
+  fun prep_dt (tvs, tname, mx, cnstrs) = 
+  let
+    val full_tname = Sign.full_name thy tname
+    val (cnstrs', cnstrs'') = 
+      split_list (map (prep_cnstr full_tname tvs) cnstrs)
+  in
+    (cnstrs', (tvs, tname, mx, cnstrs''))
+  end 
+
+  val (cnstrs, dts) = split_list (map prep_dt dt_strs)
+in
+  lthy
+  |> Local_Theory.theory (Sign.add_consts_i (flat cnstrs))
+  |> pair dts
+end
+*}
+
+ML {*
+(* parsing the binding function specification and *)
+(* declaring the functions in the local theory    *)
+fun prepare_bn_funs bn_fun_strs bn_eq_strs lthy =
+let
+  val ((bn_funs, bn_eqs), _) = 
+    Specification.read_spec bn_fun_strs bn_eq_strs lthy
+
+  fun prep_bn_fun ((bn, T), mx) = (bn, T, mx) 
+  
+  val bn_funs' = map prep_bn_fun bn_funs
+in
+  lthy
+  |> Local_Theory.theory (Sign.add_consts_i bn_funs')
+  |> pair (bn_funs', bn_eqs) 
+end 
+*}
+
+text {* associates every SOME with the index in the list; drops NONEs *}
+ML {*
+fun indexify xs =
+let
+  fun mapp _ [] = []
+    | mapp i (NONE :: xs) = mapp (i + 1) xs
+    | mapp i (SOME x :: xs) = (x, i) :: mapp (i + 1) xs
+in 
+  mapp 0 xs 
+end
+
+fun index_lookup xs x =
+  case AList.lookup (op=) xs x of
+    SOME x => x
+  | NONE => error ("Cannot find " ^ x ^ " as argument annotation.");
+*}
+
+ML {*
+fun prepare_bclauses dt_strs lthy = 
+let
+  val annos_bclauses =
+    get_cnstrs dt_strs
+    |> map (map (fn (_, antys, _, bns) => (map fst antys, bns)))
+
+  fun prep_binder env bn_str =
+    case (Syntax.read_term lthy bn_str) of
+      Free (x, _) => (NONE, index_lookup env x)
+    | Const (a, T) $ Free (x, _) => (SOME (Const (a, T)), index_lookup env x)
+    | _ => error ("The term " ^ bn_str ^ " is not allowed as binding function.")
+ 
+  fun prep_body env bn_str = index_lookup env bn_str
+
+  fun prep_mode "bind"     = BLst 
+    | prep_mode "bind_set" = BSet 
+    | prep_mode "bind_res" = BRes 
+
+  fun prep_bclause env (mode, binders, bodies) = 
+  let
+    val binders' = map (prep_binder env) binders
+    val bodies' = map (prep_body env) bodies
+  in  
+    prep_mode mode (binders', bodies')
+  end
+
+  fun prep_bclauses (annos, bclause_strs) = 
+  let
+    val env = indexify annos (* for every label, associate the index *)
+  in
+    map (prep_bclause env) bclause_strs
+  end
+in
+  map (map prep_bclauses) annos_bclauses
+end
+*}
+
+text {* 
+  adds an empty binding clause for every argument
+  that is not already part of a binding clause
+*}
+
+ML {*
+fun included i bcs = 
+let
+  fun incl (BEmy j) = i = j
+    | incl (BLst (bns, bds)) = (member (op =) (map snd bns) i) orelse (member (op =) bds i)
+    | incl (BSet (bns, bds)) = (member (op =) (map snd bns) i) orelse (member (op =) bds i)
+    | incl (BRes (bns, bds)) = (member (op =) (map snd bns) i) orelse (member (op =) bds i)
+in
+  exists incl bcs 
+end
+*}
+
+ML {* 
+fun complete dt_strs bclauses = 
+let
+  val args = 
+    get_cnstrs dt_strs
+    |> map (map (fn (_, antys, _, _) => length antys))
+
+  fun complt n bcs = 
+  let
+    fun add bcs i = (if included i bcs then [] else [BEmy i]) 
+  in
+    bcs @ (flat (map_range (add bcs) n))
+  end
+in
+  map2 (map2 complt) args bclauses
+end
+*}
+
+ML {*
+fun nominal_datatype2_cmd (dt_strs, bn_fun_strs, bn_eq_strs) lthy = 
+let
+  fun prep_typ (tvs, tname, mx, _) = (tname, length tvs, mx)
+  val lthy0 = 
+    Local_Theory.theory (Sign.add_types (map prep_typ dt_strs)) lthy
+  val (dts, lthy1) = prepare_dts dt_strs lthy0
+  val ((bn_funs, bn_eqs), lthy2) = prepare_bn_funs bn_fun_strs bn_eq_strs lthy1
+  val bclauses = prepare_bclauses dt_strs lthy2
+  val bclauses' = complete dt_strs bclauses 
+in
+  nominal_datatype2 dts bn_funs bn_eqs bclauses' lthy |> snd
+end
+
+
+(* Command Keyword *)
+
+val _ = OuterSyntax.local_theory "nominal_datatype" "test" OuterKeyword.thy_decl
+  (main_parser >> nominal_datatype2_cmd)
+*}
+
+(*
+atom_decl name
+
+nominal_datatype lam =
+  Var name
+| App lam lam
+| Lam x::name t::lam  bind_set x in t
+| Let p::pt t::lam bind_set "bn p" in t
+and pt =
+  P1 name
+| P2 pt pt
+binder
+ bn::"pt \<Rightarrow> atom set"
+where
+  "bn (P1 x) = {atom x}"
+| "bn (P2 p1 p2) = bn p1 \<union> bn p2"
+
+find_theorems Var_raw
+
+
+
+thm lam_pt.bn
+thm lam_pt.fv[simplified lam_pt.supp(1-2)]
+thm lam_pt.eq_iff
+thm lam_pt.induct
+thm lam_pt.perm
+
+nominal_datatype exp =
+  EVar name
+| EUnit
+| EPair q1::exp q2::exp
+| ELetRec l::lrbs e::exp     bind "b_lrbs l" in e l
+
+and fnclause =
+  K x::name p::pat f::exp    bind_res "b_pat p" in f
+
+and fnclauses =
+  S fnclause
+| ORs fnclause fnclauses
+
+and lrb =
+  Clause fnclauses
+
+and lrbs =
+  Single lrb
+| More lrb lrbs
+
+and pat =
+  PVar name
+| PUnit
+| PPair pat pat
+
+binder
+  b_lrbs      :: "lrbs \<Rightarrow> atom list" and
+  b_pat       :: "pat \<Rightarrow> atom set" and
+  b_fnclauses :: "fnclauses \<Rightarrow> atom list" and
+  b_fnclause  :: "fnclause \<Rightarrow> atom list" and
+  b_lrb       :: "lrb \<Rightarrow> atom list"
+
+where
+  "b_lrbs (Single l) = b_lrb l"
+| "b_lrbs (More l ls) = append (b_lrb l) (b_lrbs ls)"
+| "b_pat (PVar x) = {atom x}"
+| "b_pat (PUnit) = {}"
+| "b_pat (PPair p1 p2) = b_pat p1 \<union> b_pat p2"
+| "b_fnclauses (S fc) = (b_fnclause fc)"
+| "b_fnclauses (ORs fc fcs) = append (b_fnclause fc) (b_fnclauses fcs)"
+| "b_lrb (Clause fcs) = (b_fnclauses fcs)"
+| "b_fnclause (K x pat exp) = [atom x]"
+
+thm exp_fnclause_fnclauses_lrb_lrbs_pat.bn
+thm exp_fnclause_fnclauses_lrb_lrbs_pat.fv
+thm exp_fnclause_fnclauses_lrb_lrbs_pat.eq_iff
+thm exp_fnclause_fnclauses_lrb_lrbs_pat.induct
+thm exp_fnclause_fnclauses_lrb_lrbs_pat.perm
+
+nominal_datatype ty =
+  Vr "name"
+| Fn "ty" "ty"
+and tys =
+  Al xs::"name fset" t::"ty" bind_res xs in t
+
+thm ty_tys.fv[simplified ty_tys.supp]
+thm ty_tys.eq_iff
+
+*)
+
+(* some further tests *)
+
+(*
+nominal_datatype ty2 =
+  Vr2 "name"
+| Fn2 "ty2" "ty2"
+
+nominal_datatype tys2 =
+  All2 xs::"name fset" ty::"ty2" bind_res xs in ty
+
+nominal_datatype lam2 =
+  Var2 "name"
+| App2 "lam2" "lam2 list"
+| Lam2 x::"name" t::"lam2" bind x in t
+*)
+
+
+
+end
+
+
+