Theory Infinite_Set

Up to index of Isabelle/HOL

theory Infinite_Set
imports Hilbert_Choice Binomial
begin

(*  Title:      HOL/Infnite_Set.thy
    ID:         $Id: Infinite_Set.thy,v 1.11 2005/07/13 13:06:21 paulson Exp $
    Author:     Stephan Merz 
*)

header {* Infnite Sets and Related Concepts*}

theory Infinite_Set
imports Hilbert_Choice Binomial
begin

subsection "Infinite Sets"

text {* Some elementary facts about infinite sets, by Stefan Merz. *}

syntax
  infinite :: "'a set => bool"
translations
  "infinite S" == "S ∉ Finites"

text {*
  Infinite sets are non-empty, and if we remove some elements
  from an infinite set, the result is still infinite.
*}

lemma infinite_nonempty:
  "¬ (infinite {})"
by simp

lemma infinite_remove:
  "infinite S ==> infinite (S - {a})"
by simp

lemma Diff_infinite_finite:
  assumes T: "finite T" and S: "infinite S"
  shows "infinite (S-T)"
using T
proof (induct)
  from S
  show "infinite (S - {})" by auto
next
  fix T x
  assume ih: "infinite (S-T)"
  have "S - (insert x T) = (S-T) - {x}"
    by (rule Diff_insert)
  with ih
  show "infinite (S - (insert x T))"
    by (simp add: infinite_remove)
qed

lemma Un_infinite:
  "infinite S ==> infinite (S ∪ T)"
by simp

lemma infinite_super:
  assumes T: "S ⊆ T" and S: "infinite S"
  shows "infinite T"
proof (rule ccontr)
  assume "¬(infinite T)"
  with T
  have "finite S" by (simp add: finite_subset)
  with S
  show False by simp
qed

text {*
  As a concrete example, we prove that the set of natural
  numbers is infinite.
*}

lemma finite_nat_bounded:
  assumes S: "finite (S::nat set)"
  shows "∃k. S ⊆ {..<k}" (is "∃k. ?bounded S k")
using S
proof (induct)
  have "?bounded {} 0" by simp
  thus "∃k. ?bounded {} k" ..
next
  fix S x
  assume "∃k. ?bounded S k"
  then obtain k where k: "?bounded S k" ..
  show "∃k. ?bounded (insert x S) k"
  proof (cases "x<k")
    case True
    with k show ?thesis by auto
  next
    case False
    with k have "?bounded S (Suc x)" by auto
    thus ?thesis by auto
  qed
qed

lemma finite_nat_iff_bounded:
  "finite (S::nat set) = (∃k. S ⊆ {..<k})" (is "?lhs = ?rhs")
proof
  assume ?lhs
  thus ?rhs by (rule finite_nat_bounded)
next
  assume ?rhs
  then obtain k where "S ⊆ {..<k}" ..
  thus "finite S"
    by (rule finite_subset, simp)
qed

lemma finite_nat_iff_bounded_le:
  "finite (S::nat set) = (∃k. S ⊆ {..k})" (is "?lhs = ?rhs")
proof
  assume ?lhs
  then obtain k where "S ⊆ {..<k}" 
    by (blast dest: finite_nat_bounded)
  hence "S ⊆ {..k}" by auto
  thus ?rhs ..
next
  assume ?rhs
  then obtain k where "S ⊆ {..k}" ..
  thus "finite S"
    by (rule finite_subset, simp)
qed

lemma infinite_nat_iff_unbounded:
  "infinite (S::nat set) = (∀m. ∃n. m<n ∧ n∈S)"
  (is "?lhs = ?rhs")
proof
  assume inf: ?lhs
  show ?rhs
  proof (rule ccontr)
    assume "¬ ?rhs"
    then obtain m where m: "∀n. m<n --> n∉S" by blast
    hence "S ⊆ {..m}"
      by (auto simp add: sym[OF linorder_not_less])
    with inf show "False" 
      by (simp add: finite_nat_iff_bounded_le)
  qed
next
  assume unbounded: ?rhs
  show ?lhs
  proof
    assume "finite S"
    then obtain m where "S ⊆ {..m}"
      by (auto simp add: finite_nat_iff_bounded_le)
    hence "∀n. m<n --> n∉S" by auto
    with unbounded show "False" by blast
  qed
qed

lemma infinite_nat_iff_unbounded_le:
  "infinite (S::nat set) = (∀m. ∃n. m≤n ∧ n∈S)"
  (is "?lhs = ?rhs")
proof
  assume inf: ?lhs
  show ?rhs
  proof
    fix m
    from inf obtain n where "m<n ∧ n∈S"
      by (auto simp add: infinite_nat_iff_unbounded)
    hence "m≤n ∧ n∈S" by auto
    thus "∃n. m ≤ n ∧ n ∈ S" ..
  qed
next
  assume unbounded: ?rhs
  show ?lhs
  proof (auto simp add: infinite_nat_iff_unbounded)
    fix m
    from unbounded obtain n where "(Suc m)≤n ∧ n∈S"
      by blast
    hence "m<n ∧ n∈S" by auto
    thus "∃n. m < n ∧ n ∈ S" ..
  qed
qed

text {*
  For a set of natural numbers to be infinite, it is enough
  to know that for any number larger than some @{text k}, there
  is some larger number that is an element of the set.
*}

lemma unbounded_k_infinite:
  assumes k: "∀m. k<m --> (∃n. m<n ∧ n∈S)"
  shows "infinite (S::nat set)"
proof (auto simp add: infinite_nat_iff_unbounded)
  fix m show "∃n. m<n ∧ n∈S"
  proof (cases "k<m")
    case True
    with k show ?thesis by blast
  next
    case False
    from k obtain n where "Suc k < n ∧ n∈S" by auto
    with False have "m<n ∧ n∈S" by auto
    thus ?thesis ..
  qed
qed

theorem nat_infinite [simp]:
  "infinite (UNIV :: nat set)"
by (auto simp add: infinite_nat_iff_unbounded)

theorem nat_not_finite [elim]:
  "finite (UNIV::nat set) ==> R"
by simp

text {*
  Every infinite set contains a countable subset. More precisely
  we show that a set @{text S} is infinite if and only if there exists 
  an injective function from the naturals into @{text S}.
*}

lemma range_inj_infinite:
  "inj (f::nat => 'a) ==> infinite (range f)"
proof
  assume "inj f"
    and  "finite (range f)"
  hence "finite (UNIV::nat set)"
    by (auto intro: finite_imageD simp del: nat_infinite)
  thus "False" by simp
qed

text {*
  The ``only if'' direction is harder because it requires the
  construction of a sequence of pairwise different elements of
  an infinite set @{text S}. The idea is to construct a sequence of
  non-empty and infinite subsets of @{text S} obtained by successively
  removing elements of @{text S}.
*}

lemma linorder_injI:
  assumes hyp: "∀x y. x < (y::'a::linorder) --> f x ≠ f y"
  shows "inj f"
proof (rule inj_onI)
  fix x y
  assume f_eq: "f x = f y"
  show "x = y"
  proof (rule linorder_cases)
    assume "x < y"
    with hyp have "f x ≠ f y" by blast
    with f_eq show ?thesis by simp
  next
    assume "x = y"
    thus ?thesis .
  next
    assume "y < x"
    with hyp have "f y ≠ f x" by blast
    with f_eq show ?thesis by simp
  qed
qed

lemma infinite_countable_subset:
  assumes inf: "infinite (S::'a set)"
  shows "∃f. inj (f::nat => 'a) ∧ range f ⊆ S"
proof -
  def Sseq ≡ "nat_rec S (λn T. T - {SOME e. e ∈ T})"
  def pick ≡ "λn. (SOME e. e ∈ Sseq n)"
  have Sseq_inf: "!!n. infinite (Sseq n)"
  proof -
    fix n
    show "infinite (Sseq n)"
    proof (induct n)
      from inf show "infinite (Sseq 0)"
        by (simp add: Sseq_def)
    next
      fix n
      assume "infinite (Sseq n)" thus "infinite (Sseq (Suc n))"
        by (simp add: Sseq_def infinite_remove)
    qed
  qed
  have Sseq_S: "!!n. Sseq n ⊆ S"
  proof -
    fix n
    show "Sseq n ⊆ S"
      by (induct n, auto simp add: Sseq_def)
  qed
  have Sseq_pick: "!!n. pick n ∈ Sseq n"
  proof -
    fix n
    show "pick n ∈ Sseq n"
    proof (unfold pick_def, rule someI_ex)
      from Sseq_inf have "infinite (Sseq n)" .
      hence "Sseq n ≠ {}" by auto
      thus "∃x. x ∈ Sseq n" by auto
    qed
  qed
  with Sseq_S have rng: "range pick ⊆ S"
    by auto
  have pick_Sseq_gt: "!!n m. pick n ∉ Sseq (n + Suc m)"
  proof -
    fix n m
    show "pick n ∉ Sseq (n + Suc m)"
      by (induct m, auto simp add: Sseq_def pick_def)
  qed
  have pick_pick: "!!n m. pick n ≠ pick (n + Suc m)"
  proof -
    fix n m
    from Sseq_pick have "pick (n + Suc m) ∈ Sseq (n + Suc m)" .
    moreover from pick_Sseq_gt
    have "pick n ∉ Sseq (n + Suc m)" .
    ultimately show "pick n ≠ pick (n + Suc m)"
      by auto
  qed
  have inj: "inj pick"
  proof (rule linorder_injI)
    show "∀i j. i<(j::nat) --> pick i ≠ pick j"
    proof (clarify)
      fix i j
      assume ij: "i<(j::nat)"
        and eq: "pick i = pick j"
      from ij obtain k where "j = i + (Suc k)"
        by (auto simp add: less_iff_Suc_add)
      with pick_pick have "pick i ≠ pick j" by simp
      with eq show "False" by simp
    qed
  qed
  from rng inj show ?thesis by auto
qed

theorem infinite_iff_countable_subset:
  "infinite S = (∃f. inj (f::nat => 'a) ∧ range f ⊆ S)"
  (is "?lhs = ?rhs")
by (auto simp add: infinite_countable_subset
                   range_inj_infinite infinite_super)

text {*
  For any function with infinite domain and finite range
  there is some element that is the image of infinitely
  many domain elements. In particular, any infinite sequence
  of elements from a finite set contains some element that
  occurs infinitely often.
*}

theorem inf_img_fin_dom:
  assumes img: "finite (f`A)" and dom: "infinite A"
  shows "∃y ∈ f`A. infinite (f -` {y})"
proof (rule ccontr)
  assume "¬ (∃y∈f ` A. infinite (f -` {y}))"
  with img have "finite (UN y:f`A. f -` {y})"
    by (blast intro: finite_UN_I)
  moreover have "A ⊆ (UN y:f`A. f -` {y})" by auto
  moreover note dom
  ultimately show "False"
    by (simp add: infinite_super)
qed

theorems inf_img_fin_domE = inf_img_fin_dom[THEN bexE]


subsection "Infinitely Many and Almost All"

text {*
  We often need to reason about the existence of infinitely many
  (resp., all but finitely many) objects satisfying some predicate,
  so we introduce corresponding binders and their proof rules.
*}

consts
  Inf_many :: "('a => bool) => bool"      (binder "INF " 10)
  Alm_all  :: "('a => bool) => bool"      (binder "MOST " 10)

defs
  INF_def:  "Inf_many P ≡ infinite {x. P x}"
  MOST_def: "Alm_all P ≡ ¬(INF x. ¬ P x)"

syntax (xsymbols)
  "MOST " :: "[idts, bool] => bool"       ("(3∀_./ _)" [0,10] 10)
  "INF "    :: "[idts, bool] => bool"     ("(3∃_./ _)" [0,10] 10)

syntax (HTML output)
  "MOST " :: "[idts, bool] => bool"       ("(3∀_./ _)" [0,10] 10)
  "INF "    :: "[idts, bool] => bool"     ("(3∃_./ _)" [0,10] 10)

lemma INF_EX:
  "(∃x. P x) ==> (∃x. P x)"
proof (unfold INF_def, rule ccontr)
  assume inf: "infinite {x. P x}"
    and notP: "¬(∃x. P x)"
  from notP have "{x. P x} = {}" by simp
  hence "finite {x. P x}" by simp
  with inf show "False" by simp
qed

lemma MOST_iff_finiteNeg:
  "(∀x. P x) = finite {x. ¬ P x}"
by (simp add: MOST_def INF_def)

lemma ALL_MOST:
  "∀x. P x ==> ∀x. P x"
by (simp add: MOST_iff_finiteNeg)

lemma INF_mono:
  assumes inf: "∃x. P x" and q: "!!x. P x ==> Q x"
  shows "∃x. Q x"
proof -
  from inf have "infinite {x. P x}" by (unfold INF_def)
  moreover from q have "{x. P x} ⊆ {x. Q x}" by auto
  ultimately show ?thesis
    by (simp add: INF_def infinite_super)
qed

lemma MOST_mono:
  "[| ∀x. P x; !!x. P x ==> Q x |] ==> ∀x. Q x"
by (unfold MOST_def, blast intro: INF_mono)

lemma INF_nat: "(∃n. P (n::nat)) = (∀m. ∃n. m<n ∧ P n)"
by (simp add: INF_def infinite_nat_iff_unbounded)

lemma INF_nat_le: "(∃n. P (n::nat)) = (∀m. ∃n. m≤n ∧ P n)"
by (simp add: INF_def infinite_nat_iff_unbounded_le)

lemma MOST_nat: "(∀n. P (n::nat)) = (∃m. ∀n. m<n --> P n)"
by (simp add: MOST_def INF_nat)

lemma MOST_nat_le: "(∀n. P (n::nat)) = (∃m. ∀n. m≤n --> P n)"
by (simp add: MOST_def INF_nat_le)


subsection "Miscellaneous"

text {*
  A few trivial lemmas about sets that contain at most one element.
  These simplify the reasoning about deterministic automata.
*}

constdefs
  atmost_one :: "'a set => bool"
  "atmost_one S ≡ ∀x y. x∈S ∧ y∈S --> x=y"

lemma atmost_one_empty: "S={} ==> atmost_one S"
by (simp add: atmost_one_def)

lemma atmost_one_singleton: "S = {x} ==> atmost_one S"
by (simp add: atmost_one_def)

lemma atmost_one_unique [elim]: "[| atmost_one S; x ∈ S; y ∈ S |] ==> y=x"
by (simp add: atmost_one_def)

end

Infinite Sets

lemma infinite_nonempty:

  ¬ infinite {}

lemma infinite_remove:

  infinite S ==> infinite (S - {a})

lemma Diff_infinite_finite:

  [| finite T; infinite S |] ==> infinite (S - T)

lemma Un_infinite:

  infinite S ==> infinite (ST)

lemma infinite_super:

  [| ST; infinite S |] ==> infinite T

lemma finite_nat_bounded:

  finite S ==> ∃k. S ⊆ {..<k}

lemma finite_nat_iff_bounded:

  finite S = (∃k. S ⊆ {..<k})

lemma finite_nat_iff_bounded_le:

  finite S = (∃k. S ⊆ {..k})

lemma infinite_nat_iff_unbounded:

  infinite S = (∀m. ∃n. m < nnS)

lemma infinite_nat_iff_unbounded_le:

  infinite S = (∀m. ∃n. mnnS)

lemma unbounded_k_infinite:

m>k. ∃n. m < nnS ==> infinite S

theorem nat_infinite:

  infinite UNIV

theorem nat_not_finite:

  finite UNIV ==> R

lemma range_inj_infinite:

  inj f ==> infinite (range f)

lemma linorder_injI:

x y. x < y --> f xf y ==> inj f

lemma infinite_countable_subset:

  infinite S ==> ∃f. inj f ∧ range fS

theorem infinite_iff_countable_subset:

  infinite S = (∃f. inj f ∧ range fS)

theorem inf_img_fin_dom:

  [| finite (f ` A); infinite A |] ==> ∃yf ` A. infinite (f -` {y})

theorems inf_img_fin_domE:

  [| finite (f1 ` A1); infinite A1;
     !!x. [| xf1 ` A1; infinite (f1 -` {x}) |] ==> Q |]
  ==> Q

theorems inf_img_fin_domE:

  [| finite (f1 ` A1); infinite A1;
     !!x. [| xf1 ` A1; infinite (f1 -` {x}) |] ==> Q |]
  ==> Q

Infinitely Many and Almost All

lemma INF_EX:

x. P x ==> ∃x. P x

lemma MOST_iff_finiteNeg:

  (∀x. P x) = finite {x. ¬ P x}

lemma ALL_MOST:

x. P x ==> ∀x. P x

lemma INF_mono:

  [| ∃x. P x; !!x. P x ==> Q x |] ==> ∃x. Q x

lemma MOST_mono:

  [| ∀x. P x; !!x. P x ==> Q x |] ==> ∀x. Q x

lemma INF_nat:

  (∃n. P n) = (∀m. ∃n. m < nP n)

lemma INF_nat_le:

  (∃n. P n) = (∀m. ∃n. mnP n)

lemma MOST_nat:

  (∀n. P n) = (∃m. ∀n. m < n --> P n)

lemma MOST_nat_le:

  (∀n. P n) = (∃m. ∀n. mn --> P n)

Miscellaneous

lemma atmost_one_empty:

  S = {} ==> atmost_one S

lemma atmost_one_singleton:

  S = {x} ==> atmost_one S

lemma atmost_one_unique:

  [| atmost_one S; xS; yS |] ==> y = x