(* Title: HOL/Library/Nat_Bijection.thy
Author: Brian Huffman
Author: Florian Haftmann
Author: Stefan Richter
Author: Tobias Nipkow
Author: Alexander Krauss
*)
section ‹Bijections between natural numbers
and other
types›
theory Nat_Bijection
imports Main
begin
subsection ‹Type
🍋‹nat
× nat
››
text ‹Triangle numbers: 0, 1, 3, 6, 10, 15, ...
›
definition triangle ::
"nat \ nat"
where "triangle n = (n * Suc n) div 2"
lemma triangle_0 [simp]:
"triangle 0 = 0"
by (simp add: triangle_def)
lemma triangle_Suc [simp]:
"triangle (Suc n) = triangle n + Suc n"
by (simp add: triangle_def)
definition prod_encode ::
"nat \ nat \ nat"
where "prod_encode = (\(m, n). triangle (m + n) + m)"
text ‹In this auxiliary
function,
🍋‹triangle k + m
› is an invariant.
›
fun prod_decode_aux ::
"nat \ nat \ nat \ nat"
where "prod_decode_aux k m =
(
if m
≤ k
then (m, k - m) else prod_decode_aux (Suc k) (m - Suc k))
"
declare prod_decode_aux.simps [simp del]
definition prod_decode ::
"nat \ nat \ nat"
where "prod_decode = prod_decode_aux 0"
lemma prod_encode_prod_decode_aux:
"prod_encode (prod_decode_aux k m) = triangle k + m"
proof (
induction k m rule: prod_decode_aux.induct)
case (1 k m)
then show ?
case
by (simp add: prod_encode_def prod_decode_aux.simps)
qed
lemma prod_decode_inverse [simp]:
"prod_encode (prod_decode n) = n"
by (simp add: prod_decode_def prod_encode_prod_decode_aux)
lemma prod_decode_triangle_add:
"prod_decode (triangle k + m) = prod_decode_aux k m"
proof (induct k arbitrary: m)
case 0
then show ?
case
by (simp add: prod_decode_def)
next
case (Suc k)
then show ?
case
by (metis ab_semigroup_add_class.add_ac(1) add_diff_cancel_left
' le_add1 not_less_eq_eq prod_decode_aux.simps triangle_Suc)
qed
lemma prod_encode_inverse [simp]:
"prod_decode (prod_encode x) = x"
unfolding prod_encode_def
proof (induct x)
case (Pair a b)
then show ?
case
by (simp add: prod_decode_triangle_add prod_decode_aux.simps)
qed
lemma inj_prod_encode:
"inj_on prod_encode A"
by (rule inj_on_inverseI) (rule prod_encode_inverse)
lemma inj_prod_decode:
"inj_on prod_decode A"
by (rule inj_on_inverseI) (rule prod_decode_inverse)
lemma surj_prod_encode:
"surj prod_encode"
by (rule surjI) (rule prod_decode_inverse)
lemma surj_prod_decode:
"surj prod_decode"
by (rule surjI) (rule prod_encode_inverse)
lemma bij_prod_encode:
"bij prod_encode"
by (rule bijI [OF inj_prod_encode surj_prod_encode])
lemma bij_prod_decode:
"bij prod_decode"
by (rule bijI [OF inj_prod_decode surj_prod_decode])
lemma prod_encode_eq [simp]:
"prod_encode x = prod_encode y \ x = y"
by (rule inj_prod_encode [
THEN inj_eq])
lemma prod_decode_eq [simp]:
"prod_decode x = prod_decode y \ x = y"
by (rule inj_prod_decode [
THEN inj_eq])
text ‹Ordering properties
›
lemma le_prod_encode_1:
"a \ prod_encode (a, b)"
by (simp add: prod_encode_def)
lemma le_prod_encode_2:
"b \ prod_encode (a, b)"
by (induct b) (simp_all add: prod_encode_def)
subsection ‹Type
🍋‹nat + nat
››
definition sum_encode ::
"nat + nat \ nat"
where "sum_encode x = (case x of Inl a \ 2 * a | Inr b \ Suc (2 * b))"
definition sum_decode ::
"nat \ nat + nat"
where "sum_decode n = (if even n then Inl (n div 2) else Inr (n div 2))"
lemma sum_encode_inverse [simp]:
"sum_decode (sum_encode x) = x"
by (induct x) (simp_all add: sum_decode_def sum_encode_def)
lemma sum_decode_inverse [simp]:
"sum_encode (sum_decode n) = n"
by (simp add: even_two_times_div_two sum_decode_def sum_encode_def)
lemma inj_sum_encode:
"inj_on sum_encode A"
by (rule inj_on_inverseI) (rule sum_encode_inverse)
lemma inj_sum_decode:
"inj_on sum_decode A"
by (rule inj_on_inverseI) (rule sum_decode_inverse)
lemma surj_sum_encode:
"surj sum_encode"
by (rule surjI) (rule sum_decode_inverse)
lemma surj_sum_decode:
"surj sum_decode"
by (rule surjI) (rule sum_encode_inverse)
lemma bij_sum_encode:
"bij sum_encode"
by (rule bijI [OF inj_sum_encode surj_sum_encode])
lemma bij_sum_decode:
"bij sum_decode"
by (rule bijI [OF inj_sum_decode surj_sum_decode])
lemma sum_encode_eq:
"sum_encode x = sum_encode y \ x = y"
by (rule inj_sum_encode [
THEN inj_eq])
lemma sum_decode_eq:
"sum_decode x = sum_decode y \ x = y"
by (rule inj_sum_decode [
THEN inj_eq])
subsection ‹Type
🍋‹int
››
definition int_encode ::
"int \ nat"
where "int_encode i = sum_encode (if 0 \ i then Inl (nat i) else Inr (nat (- i - 1)))"
definition int_decode ::
"nat \ int"
where "int_decode n = (case sum_decode n of Inl a \ int a | Inr b \ - int b - 1)"
lemma int_encode_inverse [simp]:
"int_decode (int_encode x) = x"
by (simp add: int_decode_def int_encode_def)
lemma int_decode_inverse [simp]:
"int_encode (int_decode n) = n"
unfolding int_decode_def int_encode_def
using sum_decode_inverse [of n]
by (cases
"sum_decode n") simp_all
lemma inj_int_encode:
"inj_on int_encode A"
by (rule inj_on_inverseI) (rule int_encode_inverse)
lemma inj_int_decode:
"inj_on int_decode A"
by (rule inj_on_inverseI) (rule int_decode_inverse)
lemma surj_int_encode:
"surj int_encode"
by (rule surjI) (rule int_decode_inverse)
lemma surj_int_decode:
"surj int_decode"
by (rule surjI) (rule int_encode_inverse)
lemma bij_int_encode:
"bij int_encode"
by (rule bijI [OF inj_int_encode surj_int_encode])
lemma bij_int_decode:
"bij int_decode"
by (rule bijI [OF inj_int_decode surj_int_decode])
lemma int_encode_eq:
"int_encode x = int_encode y \ x = y"
by (rule inj_int_encode [
THEN inj_eq])
lemma int_decode_eq:
"int_decode x = int_decode y \ x = y"
by (rule inj_int_decode [
THEN inj_eq])
subsection ‹Type
🍋‹nat list
››
fun list_encode ::
"nat list \ nat"
where
"list_encode [] = 0"
|
"list_encode (x # xs) = Suc (prod_encode (x, list_encode xs))"
function list_decode ::
"nat \ nat list"
where
"list_decode 0 = []"
|
"list_decode (Suc n) = (case prod_decode n of (x, y) \ x # list_decode y)"
by pat_completeness auto
termination list_decode
proof -
have "\n x y. (x, y) = prod_decode n \ y < Suc n"
by (metis le_imp_less_Suc le_prod_encode_2 prod_decode_inverse)
then show ?thesis
using "termination" by blast
qed
lemma list_encode_inverse [simp]:
"list_decode (list_encode x) = x"
by (induct x rule: list_encode.induct) simp_all
lemma list_decode_inverse [simp]:
"list_encode (list_decode n) = n"
proof (induct n rule: list_decode.induct)
case (2 n)
then show ?
case
by (metis list_encode.simps(2) list_encode_inverse prod_decode_inverse surj_pair)
qed auto
lemma inj_list_encode:
"inj_on list_encode A"
by (rule inj_on_inverseI) (rule list_encode_inverse)
lemma inj_list_decode:
"inj_on list_decode A"
by (rule inj_on_inverseI) (rule list_decode_inverse)
lemma surj_list_encode:
"surj list_encode"
by (rule surjI) (rule list_decode_inverse)
lemma surj_list_decode:
"surj list_decode"
by (rule surjI) (rule list_encode_inverse)
lemma bij_list_encode:
"bij list_encode"
by (rule bijI [OF inj_list_encode surj_list_encode])
lemma bij_list_decode:
"bij list_decode"
by (rule bijI [OF inj_list_decode surj_list_decode])
lemma list_encode_eq:
"list_encode x = list_encode y \ x = y"
by (rule inj_list_encode [
THEN inj_eq])
lemma list_decode_eq:
"list_decode x = list_decode y \ x = y"
by (rule inj_list_decode [
THEN inj_eq])
subsection ‹Finite sets of naturals
›
subsubsection
‹Preliminaries
›
lemma finite_vimage_Suc_iff:
"finite (Suc -` F) \ finite F"
proof
have "F \ insert 0 (Suc ` Suc -` F)"
using nat.nchotomy
by force
moreover
assume "finite (Suc -` F)"
then have "finite (insert 0 (Suc ` Suc -` F))"
by blast
ultimately show "finite F"
using finite_subset
by blast
qed (force intro: finite_vimageI inj_Suc)
lemma vimage_Suc_insert_0:
"Suc -` insert 0 A = Suc -` A"
by auto
lemma vimage_Suc_insert_Suc:
"Suc -` insert (Suc n) A = insert n (Suc -` A)"
by auto
lemma div2_even_ext_nat:
fixes x y :: nat
assumes "x div 2 = y div 2"
and "even x \ even y"
shows "x = y"
proof -
from ‹even x
⟷ even y
› have "x mod 2 = y mod 2"
by (simp only: even_iff_mod_2_eq_zero) auto
with assms
have "x div 2 * 2 + x mod 2 = y div 2 * 2 + y mod 2"
by simp
then show ?thesis
by simp
qed
subsubsection
‹From sets
to naturals
›
definition set_encode ::
"nat set \ nat"
where "set_encode = sum ((^) 2)"
lemma set_encode_empty [simp]:
"set_encode {} = 0"
by (simp add: set_encode_def)
lemma set_encode_inf:
"\ finite A \ set_encode A = 0"
by (simp add: set_encode_def)
lemma set_encode_insert [simp]:
"finite A \ n \ A \ set_encode (insert n A) = 2^n + set_encode A"
by (simp add: set_encode_def)
lemma even_set_encode_iff:
"finite A \ even (set_encode A) \ 0 \ A"
by (induct set: finite) (auto simp: set_encode_def)
lemma set_encode_vimage_Suc:
"set_encode (Suc -` A) = set_encode A div 2"
proof (
induction A rule: infinite_finite_induct)
case (infinite A)
then show ?
case
by (simp add: finite_vimage_Suc_iff set_encode_inf)
next
case (insert x A)
show ?
case
proof (cases x)
case 0
with insert
show ?thesis
by (simp add: even_set_encode_iff vimage_Suc_insert_0)
next
case (Suc y)
with insert
show ?thesis
by (simp add: finite_vimageI add.commute vimage_Suc_insert_Suc)
qed
qed auto
lemmas set_encode_div_2 = set_encode_vimage_Suc [symmetric]
subsubsection
‹From naturals
to sets
›
definition set_decode ::
"nat \ nat set"
where "set_decode x = {n. odd (x div 2 ^ n)}"
lemma set_decode_0 [simp]:
"0 \ set_decode x \ odd x"
by (simp add: set_decode_def)
lemma set_decode_Suc [simp]:
"Suc n \ set_decode x \ n \ set_decode (x div 2)"
by (simp add: set_decode_def div_mult2_eq)
lemma set_decode_zero [simp]:
"set_decode 0 = {}"
by (simp add: set_decode_def)
lemma set_decode_div_2:
"set_decode (x div 2) = Suc -` set_decode x"
by auto
lemma set_decode_plus_power_2:
"n \ set_decode z \ set_decode (2 ^ n + z) = insert n (set_decode z)"
proof (induct n arbitrary: z)
case 0
show ?
case
proof (rule set_eqI)
show "q \ set_decode (2 ^ 0 + z) \ q \ insert 0 (set_decode z)" for q
by (induct q) (
use 0
in simp_all)
qed
next
case (Suc n)
show ?
case
proof (rule set_eqI)
show "q \ set_decode (2 ^ Suc n + z) \ q \ insert (Suc n) (set_decode z)" for q
by (induct q) (
use Suc
in simp_all)
qed
qed
lemma finite_set_decode [simp]:
"finite (set_decode n)"
proof (
induction n rule: less_induct)
case (less n)
show ?
case
proof (cases
"n = 0")
case False
then show ?thesis
using less.IH [of
"n div 2"] finite_vimage_Suc_iff set_decode_div_2
by auto
qed auto
qed
subsubsection
‹Proof of isomorphism
›
lemma set_decode_inverse [simp]:
"set_encode (set_decode n) = n"
proof (
induction n rule: less_induct)
case (less n)
show ?
case
proof (cases
"n = 0")
case False
then have "set_encode (set_decode (n div 2)) = n div 2"
using less.IH
by auto
then show ?thesis
by (metis div2_even_ext_nat even_set_encode_iff finite_set_decode set_decode_0 set_dec
ode_div_2 set_encode_div_2)
qed auto
qed
lemma set_encode_inverse [simp]: "finite A \ set_decode (set_encode A) = A"
proof (induction rule: finite_induct)
case (insert x A)
then show ?case
by (simp add: set_decode_plus_power_2)
qed auto
lemma inj_on_set_encode: "inj_on set_encode (Collect finite)"
by (rule inj_on_inverseI [where g = "set_decode"]) simp
lemma set_encode_eq: "finite A \ finite B \ set_encode A = set_encode B \ A = B"
by (rule iffI) (simp_all add: inj_onD [OF inj_on_set_encode])
lemma subset_decode_imp_le:
assumes "set_decode m \ set_decode n"
shows "m \ n"
proof -
have "n = m + set_encode (set_decode n - set_decode m)"
proof -
obtain A B where
"m = set_encode A" "finite A"
"n = set_encode B" "finite B"
by (metis finite_set_decode set_decode_inverse)
with assms show ?thesis
by auto (simp add: set_encode_def add.commute sum.subset_diff)
qed
then show ?thesis
by (metis le_add1)
qed
end
