Theory HOL-Library.Countable

(*  Title:      HOL/Library/Countable.thy
    Author:     Alexander Krauss, TU Muenchen
    Author:     Brian Huffman, Portland State University
    Author:     Jasmin Blanchette, TU Muenchen
*)

section Encoding (almost) everything into natural numbers

theory Countable
imports Old_Datatype HOL.Rat Nat_Bijection
begin

subsection The class of countable types

class countable =
  assumes ex_inj: "to_nat :: 'a  nat. inj to_nat"

lemma countable_classI:
  fixes f :: "'a  nat"
  assumes "x y. f x = f y  x = y"
  shows "OFCLASS('a, countable_class)"
proof (intro_classes, rule exI)
  show "inj f"
    by (rule injI [OF assms]) assumption
qed


subsection Conversion functions

definition to_nat :: "'a::countable  nat" where
  "to_nat = (SOME f. inj f)"

definition from_nat :: "nat  'a::countable" where
  "from_nat = inv (to_nat :: 'a  nat)"

lemma inj_to_nat [simp]: "inj to_nat"
  by (rule exE_some [OF ex_inj]) (simp add: to_nat_def)

lemma inj_on_to_nat[simp, intro]: "inj_on to_nat S"
  using inj_to_nat by (auto simp: inj_on_def)

lemma surj_from_nat [simp]: "surj from_nat"
  unfolding from_nat_def by (simp add: inj_imp_surj_inv)

lemma to_nat_split [simp]: "to_nat x = to_nat y  x = y"
  using injD [OF inj_to_nat] by auto

lemma from_nat_to_nat [simp]:
  "from_nat (to_nat x) = x"
  by (simp add: from_nat_def)


subsection Finite types are countable

subclass (in finite) countable
proof
  have "finite (UNIV::'a set)" by (rule finite_UNIV)
  with finite_conv_nat_seg_image [of "UNIV::'a set"]
  obtain n and f :: "nat  'a"
    where "UNIV = f ` {i. i < n}" by auto
  then have "surj f" unfolding surj_def by auto
  then have "inj (inv f)" by (rule surj_imp_inj_inv)
  then show "to_nat :: 'a  nat. inj to_nat" by (rule exI[of inj])
qed


subsection Automatically proving countability of old-style datatypes

context
begin

qualified inductive finite_item :: "'a Old_Datatype.item  bool" where
  undefined: "finite_item undefined"
| In0: "finite_item x  finite_item (Old_Datatype.In0 x)"
| In1: "finite_item x  finite_item (Old_Datatype.In1 x)"
| Leaf: "finite_item (Old_Datatype.Leaf a)"
| Scons: "finite_item x; finite_item y  finite_item (Old_Datatype.Scons x y)"

qualified function nth_item :: "nat  ('a::countable) Old_Datatype.item"
where
  "nth_item 0 = undefined"
| "nth_item (Suc n) =
  (case sum_decode n of
    Inl i 
    (case sum_decode i of
      Inl j  Old_Datatype.In0 (nth_item j)
    | Inr j  Old_Datatype.In1 (nth_item j))
  | Inr i 
    (case sum_decode i of
      Inl j  Old_Datatype.Leaf (from_nat j)
    | Inr j 
      (case prod_decode j of
        (a, b)  Old_Datatype.Scons (nth_item a) (nth_item b))))"
by pat_completeness auto

lemma le_sum_encode_Inl: "x  y  x  sum_encode (Inl y)"
unfolding sum_encode_def by simp

lemma le_sum_encode_Inr: "x  y  x  sum_encode (Inr y)"
unfolding sum_encode_def by simp

qualified termination
by (relation "measure id")
  (auto simp flip: sum_encode_eq prod_encode_eq
    simp: le_imp_less_Suc le_sum_encode_Inl le_sum_encode_Inr
    le_prod_encode_1 le_prod_encode_2)

lemma nth_item_covers: "finite_item x  n. nth_item n = x"
proof (induct set: finite_item)
  case undefined
  have "nth_item 0 = undefined" by simp
  thus ?case ..
next
  case (In0 x)
  then obtain n where "nth_item n = x" by fast
  hence "nth_item (Suc (sum_encode (Inl (sum_encode (Inl n))))) = Old_Datatype.In0 x" by simp
  thus ?case ..
next
  case (In1 x)
  then obtain n where "nth_item n = x" by fast
  hence "nth_item (Suc (sum_encode (Inl (sum_encode (Inr n))))) = Old_Datatype.In1 x" by simp
  thus ?case ..
next
  case (Leaf a)
  have "nth_item (Suc (sum_encode (Inr (sum_encode (Inl (to_nat a)))))) = Old_Datatype.Leaf a"
    by simp
  thus ?case ..
next
  case (Scons x y)
  then obtain i j where "nth_item i = x" and "nth_item j = y" by fast
  hence "nth_item
    (Suc (sum_encode (Inr (sum_encode (Inr (prod_encode (i, j))))))) = Old_Datatype.Scons x y"
    by simp
  thus ?case ..
qed

theorem countable_datatype:
  fixes Rep :: "'b  ('a::countable) Old_Datatype.item"
  fixes Abs :: "('a::countable) Old_Datatype.item  'b"
  fixes rep_set :: "('a::countable) Old_Datatype.item  bool"
  assumes type: "type_definition Rep Abs (Collect rep_set)"
  assumes finite_item: "x. rep_set x  finite_item x"
  shows "OFCLASS('b, countable_class)"
proof
  define f where "f y = (LEAST n. nth_item n = Rep y)" for y
  {
    fix y :: 'b
    have "rep_set (Rep y)"
      using type_definition.Rep [OF type] by simp
    hence "finite_item (Rep y)"
      by (rule finite_item)
    hence "n. nth_item n = Rep y"
      by (rule nth_item_covers)
    hence "nth_item (f y) = Rep y"
      unfolding f_def by (rule LeastI_ex)
    hence "Abs (nth_item (f y)) = y"
      using type_definition.Rep_inverse [OF type] by simp
  }
  hence "inj f"
    by (rule inj_on_inverseI)
  thus "f::'b  nat. inj f"
    by - (rule exI)
qed

ML 
  fun old_countable_datatype_tac ctxt =
    SUBGOAL (fn (goal, _) =>
      let
        val ty_name =
          (case goal of
            (_ $ Const (const_namePure.type, Type (type_nameitself, [Type (n, _)]))) => n
          | _ => raise Match)
        val typedef_info = hd (Typedef.get_info ctxt ty_name)
        val typedef_thm = #type_definition (snd typedef_info)
        val pred_name =
          (case HOLogic.dest_Trueprop (Thm.concl_of typedef_thm) of
            (_ $ _ $ _ $ (_ $ Const (n, _))) => n
          | _ => raise Match)
        val induct_info = Inductive.the_inductive_global ctxt pred_name
        val pred_names = #names (fst induct_info)
        val induct_thms = #inducts (snd induct_info)
        val alist = pred_names ~~ induct_thms
        val induct_thm = the (AList.lookup (op =) alist pred_name)
        val vars = rev (Term.add_vars (Thm.prop_of induct_thm) [])
        val insts = vars |> map (fn (_, T) => try (Thm.cterm_of ctxt)
          (Const (const_nameCountable.finite_item, T)))
        val induct_thm' = Thm.instantiate' [] insts induct_thm
        val rules = @{thms finite_item.intros}
      in
        SOLVED' (fn i => EVERY
          [resolve_tac ctxt @{thms countable_datatype} i,
           resolve_tac ctxt [typedef_thm] i,
           eresolve_tac ctxt [induct_thm'] i,
           REPEAT (resolve_tac ctxt rules i ORELSE assume_tac ctxt i)]) 1
      end)


end


subsection Automatically proving countability of datatypes

ML_file ../Tools/BNF/bnf_lfp_countable.ML

ML 
fun countable_datatype_tac ctxt st =
  (case tryHEADGOAL (old_countable_datatype_tac ctxt) st of
    SOME res => res
  | NONE => BNF_LFP_Countable.countable_datatype_tac ctxt st);

(* compatibility *)
fun countable_tac ctxt =
  SELECT_GOAL (countable_datatype_tac ctxt);


method_setup countable_datatype = 
  Scan.succeed (SIMPLE_METHOD o countable_datatype_tac)
 "prove countable class instances for datatypes"


subsection More Countable types

text Naturals

instance nat :: countable
  by (rule countable_classI [of "id"]) simp

text Pairs

instance prod :: (countable, countable) countable
  by (rule countable_classI [of "λ(x, y). prod_encode (to_nat x, to_nat y)"])
    (auto simp add: prod_encode_eq)

text Sums

instance sum :: (countable, countable) countable
  by (rule countable_classI [of "(λx. case x of Inl a  to_nat (False, to_nat a)
                                     | Inr b  to_nat (True, to_nat b))"])
    (simp split: sum.split_asm)

text Integers

instance int :: countable
  by (rule countable_classI [of int_encode]) (simp add: int_encode_eq)

text Options

instance option :: (countable) countable
  by countable_datatype

text Lists

instance list :: (countable) countable
  by countable_datatype

text String literals

instance String.literal :: countable
  by (rule countable_classI [of "to_nat  String.explode"]) (simp add: String.explode_inject)

text Functions

instance "fun" :: (finite, countable) countable
proof
  obtain xs :: "'a list" where xs: "set xs = UNIV"
    using finite_list [OF finite_UNIV] ..
  show "to_nat::('a  'b)  nat. inj to_nat"
  proof
    show "inj (λf. to_nat (map f xs))"
      by (rule injI, simp add: xs fun_eq_iff)
  qed
qed

text Typereps

instance typerep :: countable
  by countable_datatype


subsection The rationals are countably infinite

definition nat_to_rat_surj :: "nat  rat" where
  "nat_to_rat_surj n = (let (a, b) = prod_decode n in Fract (int_decode a) (int_decode b))"

lemma surj_nat_to_rat_surj: "surj nat_to_rat_surj"
unfolding surj_def
proof
  fix r::rat
  show "n. r = nat_to_rat_surj n"
  proof (cases r)
    fix i j assume [simp]: "r = Fract i j" and "j > 0"
    have "r = (let m = int_encode i; n = int_encode j in nat_to_rat_surj (prod_encode (m, n)))"
      by (simp add: Let_def nat_to_rat_surj_def)
    thus "n. r = nat_to_rat_surj n" by(auto simp: Let_def)
  qed
qed

lemma Rats_eq_range_nat_to_rat_surj: " = range nat_to_rat_surj"
  by (simp add: Rats_def surj_nat_to_rat_surj)

context field_char_0
begin

lemma Rats_eq_range_of_rat_o_nat_to_rat_surj:
  " = range (of_rat  nat_to_rat_surj)"
  using surj_nat_to_rat_surj
  by (auto simp: Rats_def image_def surj_def) (blast intro: arg_cong[where f = of_rat])

lemma surj_of_rat_nat_to_rat_surj:
  "r    n. r = of_rat (nat_to_rat_surj n)"
  by (simp add: Rats_eq_range_of_rat_o_nat_to_rat_surj image_def)

end

instance rat :: countable
proof
  show "to_nat::rat  nat. inj to_nat"
  proof
    have "surj nat_to_rat_surj"
      by (rule surj_nat_to_rat_surj)
    then show "inj (inv nat_to_rat_surj)"
      by (rule surj_imp_inj_inv)
  qed
qed

theorem rat_denum: "f :: nat  rat. surj f"
 using surj_nat_to_rat_surj by metis

end