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Enderton (set). Finish equinumerosity theorems.

finite-set-exercises
Joshua Potter 2023-09-17 12:07:24 -06:00
parent 7959c474a0
commit 2a85d526d7
7 changed files with 465 additions and 125 deletions
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26
Bookshelf/Enderton/Set.tex
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@ -150,6 +150,9 @@
\lean*{Mathlib/Init/Function}
{Function.Bijective}
\lean{Mathlib/Data/Set/Function}
{Set.BijOn}
\lean{Mathlib/Logic/Equiv/Defs}
{Equiv}
@ -8973,7 +8976,7 @@
Hence no finite set is equinumerous to a proper subset of itself.
\end{proof}
\subsection{\pending{Corollary 6D}}%
\subsection{\verified{Corollary 6D}}%
\hyperlabel{sub:corollary-6d}
\begin{corollary}[6D]
@ -8984,6 +8987,12 @@
\end{enumerate}
\end{corollary}
\code{Bookshelf/Enderton/Set/Chapter\_6}
{Enderton.Set.Chapter\_6.corollary\_6d\_a}
\code{Bookshelf/Enderton/Set/Chapter\_6}
{Enderton.Set.Chapter\_6.corollary\_6d\_b}
\begin{proof}
\paragraph{(a)}%
@ -9034,13 +9043,16 @@
\end{proof}
\subsection{\pending{Corollary 6E}}%
\subsection{\verified{Corollary 6E}}%
\hyperlabel{sub:corollary-6e}
\begin{corollary}[6E]
Any finite set is equinumerous to a unique natural number.
\end{corollary}
\code{Bookshelf/Enderton/Set/Chapter\_6}
{Enderton.Set.Chapter\_6.corollary\_6e}
\begin{proof}
Let $S$ be a \nameref{ref:finite-set}.
By definition $S$ is equinumerous to a natural number $n$.
@ -9057,7 +9069,7 @@
number.
\end{proof}
\subsection{\pending{Lemma 6F}}%
\subsection{\verified{Lemma 6F}}%
\hyperlabel{sub:lemma-6f}
\begin{lemma}[6F]
@ -9065,6 +9077,9 @@
some $m$ less than $n$.
\end{lemma}
\code{Bookshelf/Enderton/Set/Chapter\_6}
{Enderton.Set.Chapter\_6.lemma\_6f}
\begin{proof}
Let
@ -9132,13 +9147,16 @@
\end{proof}
\subsection{\pending{Corollary 6G}}%
\subsection{\verified{Corollary 6G}}%
\hyperlabel{sub:corollary-6g}
\begin{corollary}[6G]
Any subset of a finite set is finite.
\end{corollary}
\code{Bookshelf/Enderton/Set/Chapter\_6}
{Enderton.Set.Chapter\_6.corollary\_6g}
\begin{proof}
Let $S$ be a \nameref{ref:finite-set} and $S' \subseteq S$.
Clearly, if $S' = S$, then $S'$ is finite.

388
Bookshelf/Enderton/Set/Chapter_6.lean
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@ -1,7 +1,9 @@
import Bookshelf.Enderton.Set.Chapter_4
import Common.Logic.Basic
import Common.Nat.Basic
import Common.Set.Basic
import Common.Set.Finite
import Common.Set.Equinumerous
import Common.Set.Intervals
import Mathlib.Data.Finset.Card
import Mathlib.Data.Set.Finite
import Mathlib.Tactic.LibrarySearch
@ -23,7 +25,8 @@ namespace Enderton.Set.Chapter_6
No set is equinumerous to its powerset.
-/
theorem theorem_6b (A : Set α)
: ∀ f, ¬ Set.BijOn f A (𝒫 A) := by
: A ≉ 𝒫 A := by
rw [Set.not_equinumerous_def]
intro f hf
unfold Set.BijOn at hf
let φ := { a ∈ A | a ∉ f a }
@ -287,82 +290,71 @@ lemma pigeonhole_principle_aux (n : )
No natural number is equinumerous to a proper subset of itself.
-/
theorem pigeonhole_principle {n : }
: ∀ M, M ⊂ Set.Iio n → ∀ f, ¬ Set.BijOn f M (Set.Iio n) := by
intro M hM f nf
have := pigeonhole_principle_aux n M hM f ⟨nf.left, nf.right.left⟩
exact absurd nf.right.right this
: ∀ {M}, M ⊂ Set.Iio n → M ≉ Set.Iio n := by
intro M hM nM
have ⟨f, hf⟩ := nM
have := pigeonhole_principle_aux n M hM f ⟨hf.left, hf.right.left⟩
exact absurd hf.right.right this
/-- #### Corollary 6C
No finite set is equinumerous to a proper subset of itself.
-/
theorem corollary_6c [DecidableEq α] [Nonempty α] {S S' : Finset α} (h : S' ⊂ S)
: ∀ f, ¬ Set.BijOn f S.toSet S'.toSet := by
have ⟨T, hT₁, hT₂⟩ : ∃ T, Disjoint S' T ∧ S = S' T := by
refine ⟨S \ S', ?_, ?_⟩
· intro X hX₁ hX₂
show ∀ t, t ∈ X → t ∈ ⊥
intro t ht
have ht₂ := hX₂ ht
simp only [Finset.mem_sdiff] at ht₂
exact absurd (hX₁ ht) ht₂.right
· simp only [
Finset.union_sdiff_self_eq_union,
Finset.right_eq_union_iff_subset
]
exact subset_of_ssubset h
theorem corollary_6c [DecidableEq α] [Nonempty α]
{S S' : Set α} (hS : Set.Finite S) (h : S' ⊂ S)
: S ≉ S' := by
let T := S \ S'
have hT : S = S' (S \ S') := by
simp only [Set.union_diff_self]
exact (Set.left_subset_union_eq_self (subset_of_ssubset h)).symm
-- `hF : S' T ≈ S`.
-- `hG : S ≈ n`.
-- `hH : S' T ≈ n`.
have ⟨F, hF := Set.equinumerous_refl S.toSet
conv at hF => arg 2; rw [hT₂]
have ⟨n, G, hG⟩ := Set.finite_iff_equinumerous_nat.mp (Finset.finite_toSet S)
have hF := Set.equinumerous_refl S
conv at hF => arg 1; rw [hT]
have ⟨n, hG⟩ := Set.finite_iff_equinumerous_nat.mp hS
have ⟨H, hH⟩ := Set.equinumerous_trans hF hG
-- Restrict `H` to `S'` to yield a bijection between `S'` and `m < n`.
-- Restrict `H` to `S'` to yield a bijection between `S'` and a proper subset
-- of `n`.
let R := (Set.Iio n) \ (H '' T)
have hR : Set.BijOn H S' R := by
refine ⟨?_, ?_, ?_⟩
· -- `Set.MapsTo H S' R`
intro x hx
refine ⟨hH.left $ Finset.mem_union_left T hx, ?_⟩
refine ⟨hH.left $ Set.mem_union_left T hx, ?_⟩
unfold Set.image
by_contra nx
simp only [Finset.mem_coe, Set.mem_setOf_eq] at nx
have ⟨a, ha₁, ha₂⟩ := nx
have hc₁ : a ∈ S' T := Finset.mem_union_right S' ha₁
have hc₂ : x ∈ S' T := Finset.mem_union_left T hx
have hc₁ : a ∈ S' T := Set.mem_union_right S' ha₁
have hc₂ : x ∈ S' T := Set.mem_union_left T hx
rw [hH.right.left hc₁ hc₂ ha₂] at ha₁
have hx₁ : {x} ⊆ S' := Finset.singleton_subset_iff.mpr hx
have hx₂ : {x} ⊆ T := Finset.singleton_subset_iff.mpr ha₁
have hx₃ := hT₁ hx₁ hx₂
have hx₁ : {x} ⊆ S' := Set.singleton_subset_iff.mpr hx
have hx₂ : {x} ⊆ T := Set.singleton_subset_iff.mpr ha₁
have hx₃ := Set.disjoint_sdiff_right hx₁ hx₂
simp only [
Finset.bot_eq_empty,
Finset.le_eq_subset,
Finset.singleton_subset_iff,
Finset.not_mem_empty
] at hx₃
Set.bot_eq_empty,
Set.le_eq_subset,
Set.singleton_subset_iff,
Set.mem_empty_iff_false
] at hx₃
· -- `Set.InjOn H S'`
intro x₁ hx₁ x₂ hx₂ h
have hc₁ : x₁ ∈ S' T := Finset.mem_union_left T hx₁
have hc₂ : x₂ ∈ S' T := Finset.mem_union_left T hx₂
have hc₁ : x₁ ∈ S' T := Set.mem_union_left T hx₁
have hc₂ : x₂ ∈ S' T := Set.mem_union_left T hx₂
exact hH.right.left hc₁ hc₂ h
· -- `Set.SurjOn H S' R`
show ∀ r, r ∈ R → r ∈ H '' S'
intro r hr
unfold Set.image
simp only [Finset.mem_coe, Set.mem_setOf_eq]
simp only [Set.mem_setOf_eq]
dsimp only at hr
have := hH.right.right hr.left
simp only [
Finset.coe_union,
Set.mem_image,
Set.mem_union,
Finset.mem_coe
] at this
simp only [Set.mem_image, Set.mem_union] at this
have ⟨x, hx⟩ := this
apply Or.elim hx.left
· intro hx'
@ -372,15 +364,14 @@ theorem corollary_6c [DecidableEq α] [Nonempty α] {S S' : Finset α} (h : S'
rw [← hx.right]
simp only [Set.mem_image, Finset.mem_coe]
exact ⟨x, hx', rfl⟩
intro f nf
have ⟨f₁, hf₁⟩ : ∃ f₁ : α, Set.BijOn f₁ S R :=
Set.equinumerous_trans nf hR
have ⟨f₂, hf₂⟩ : ∃ f₃ : , Set.BijOn f₃ R (Set.Iio n) := by
have ⟨k, hk₁⟩ := Set.equinumerous_symm hf₁
exact Set.equinumerous_trans hk₁ hG
intro hf
have hf₁ : S ≈ R := Set.equinumerous_trans hf ⟨H, hR⟩
have hf₂ : R ≈ Set.Iio n := by
have ⟨k, hk⟩ := Set.equinumerous_symm hf₁
exact Set.equinumerous_trans ⟨k, hk⟩ hG
refine absurd hf₂ (pigeonhole_principle R ?_ f₂)
refine absurd hf₂ (pigeonhole_principle ?_)
show R ⊂ Set.Iio n
apply And.intro
· show ∀ r, r ∈ R → r ∈ Set.Iio n
@ -388,17 +379,8 @@ theorem corollary_6c [DecidableEq α] [Nonempty α] {S S' : Finset α} (h : S'
exact hr.left
· show ¬ ∀ r, r ∈ Set.Iio n → r ∈ R
intro nr
have ⟨t, ht₁⟩ : Finset.Nonempty T := by
rw [hT₂, Finset.ssubset_def] at h
have : ¬ ∀ x, x ∈ S' T → x ∈ S' := h.right
simp only [Finset.mem_union, not_forall, exists_prop] at this
have ⟨x, hx⟩ := this
apply Or.elim hx.left
· intro nx
exact absurd nx hx.right
· intro hx
exact ⟨x, hx⟩
have ht₂ : H t ∈ Set.Iio n := hH.left (Finset.mem_union_right S' ht₁)
have ⟨t, ht₁⟩ : Set.Nonempty T := Set.diff_ssubset_nonempty h
have ht₂ : H t ∈ Set.Iio n := hH.left (Set.mem_union_right S' ht₁)
have ht₃ : H t ∈ R := nr (H t) ht₂
exact absurd ⟨t, ht₁, rfl⟩ ht₃.right
@ -406,9 +388,12 @@ theorem corollary_6c [DecidableEq α] [Nonempty α] {S S' : Finset α} (h : S'
Any set equinumerous to a proper subset of itself is infinite.
-/
theorem corollary_6d_a (S S' : Set α) (hS : S' ⊂ S) (hf : S' ≃ S)
theorem corollary_6d_a [DecidableEq α] [Nonempty α]
{S S' : Set α} (hS : S' ⊂ S) (hf : S ≈ S')
: Set.Infinite S := by
sorry
by_contra nS
simp only [Set.not_infinite] at nS
exact absurd hf (corollary_6c nS hS)
/-- #### Corollary 6D (b)
@ -416,28 +401,279 @@ The set `ω` is infinite.
-/
theorem corollary_6d_b
: Set.Infinite (@Set.univ ) := by
sorry
let S : Set := { 2 * n | n ∈ @Set.univ }
let f x := 2 * x
suffices Set.BijOn f (@Set.univ ) S by
refine corollary_6d_a ?_ ⟨f, this⟩
rw [Set.ssubset_def]
apply And.intro
· simp
· show ¬ ∀ x, x ∈ Set.univ → x ∈ S
simp only [
Set.mem_univ,
true_and,
Set.mem_setOf_eq,
forall_true_left,
not_forall,
not_exists
]
refine ⟨1, ?_⟩
intro x nx
simp only [mul_eq_one, false_and] at nx
refine ⟨by simp, ?_, ?_⟩
· -- `Set.InjOn f Set.univ`
intro n₁ _ n₂ _ hf
match @trichotomous LT.lt _ n₁ n₂ with
| Or.inr (Or.inl r) => exact r
| Or.inl r =>
have := (Chapter_4.theorem_4n_ii n₁ n₂ 1).mp r
conv at this => left; rw [mul_comm]
conv at this => right; rw [mul_comm]
exact absurd hf (Nat.ne_of_lt this)
| Or.inr (Or.inr r) =>
have := (Chapter_4.theorem_4n_ii n₂ n₁ 1).mp r
conv at this => left; rw [mul_comm]
conv at this => right; rw [mul_comm]
exact absurd hf.symm (Nat.ne_of_lt this)
· -- `Set.SurjOn f Set.univ S`
show ∀ x, x ∈ S → x ∈ f '' Set.univ
intro x hx
unfold Set.image
simp only [Set.mem_univ, true_and, Set.mem_setOf_eq] at hx ⊢
exact hx
/-- #### Corollary 6E
Any finite set is equinumerous to a unique natural number.
-/
theorem corollary_6e (S : Set α) (hn : S ≃ Fin n) (hm : S ≃ Fin m)
: m = n := by
sorry
theorem corollary_6e [Nonempty α] (S : Set α) (hS : Set.Finite S)
: ∃! n : , S ≈ Set.Iio n := by
have ⟨n, hf⟩ := Set.finite_iff_equinumerous_nat.mp hS
refine ⟨n, hf, ?_⟩
intro m hg
match @trichotomous LT.lt _ m n with
| Or.inr (Or.inl r) => exact r
| Or.inl r =>
have hh := Set.equinumerous_symm hg
have hk := Set.equinumerous_trans hh hf
have hmn : Set.Iio m ⊂ Set.Iio n := Set.Iio_nat_lt_ssubset r
exact absurd hk (pigeonhole_principle hmn)
| Or.inr (Or.inr r) =>
have hh := Set.equinumerous_symm hf
have hk := Set.equinumerous_trans hh hg
have hnm : Set.Iio n ⊂ Set.Iio m := Set.Iio_nat_lt_ssubset r
exact absurd hk (pigeonhole_principle hnm)
/-- #### Lemma 6F
If `C` is a proper subset of a natural number `n`, then `C ≈ m` for some `m`
less than `n`.
-/
lemma lemma_6f {n : } (hC : C ⊂ Finset.range n)
: ∃ m : , m < n ∧ ∃ f : C → Fin m, Function.Bijective f := by
sorry
lemma lemma_6f {n : }
: ∀ {C}, C ⊂ Set.Iio n → ∃ m, m < n ∧ C ≈ Set.Iio m := by
induction n with
| zero =>
intro C hC
unfold Set.Iio at hC
simp only [Nat.zero_eq, not_lt_zero', Set.setOf_false] at hC
rw [Set.ssubset_empty_iff_false] at hC
exact False.elim hC
| succ n ih =>
have h_subset_equinumerous
: ∀ S, S ⊆ Set.Iio n →
∃ m, m < n + 1 ∧ S ≈ Set.Iio m := by
intro S hS
rw [subset_iff_ssubset_or_eq] at hS
apply Or.elim hS
· -- `S ⊂ Set.Iio n`
intro h
have ⟨m, hm⟩ := ih h
exact ⟨m, calc m
_ < n := hm.left
_ < n + 1 := by simp, hm.right⟩
· -- `S = Set.Iio n`
intro h
exact ⟨n, by simp, Set.eq_imp_equinumerous h⟩
theorem corollary_6g (S S' : Set α) (hS : Finite S) (hS' : S' ⊆ S)
: Finite S' := by
sorry
intro C hC
by_cases hn : n ∈ C
· -- Since `C` is a proper subset of `n⁺`, the set `n⁺ - C` is nonempty.
have hC₁ : Set.Nonempty (Set.Iio (n + 1) \ C) := by
rw [Set.ssubset_def] at hC
have : ¬ ∀ x, x ∈ Set.Iio (n + 1) → x ∈ C := hC.right
simp only [Set.mem_Iio, not_forall, exists_prop] at this
exact this
-- `p` is the least element of `n⁺ - C`.
have ⟨p, hp⟩ := Chapter_4.well_ordering_nat hC₁
let C' := (C \ {n}) {p}
have hC'₁ : C' ⊆ Set.Iio n := by
show ∀ x, x ∈ C' → x ∈ Set.Iio n
intro x hx
match @trichotomous LT.lt _ x n with
| Or.inl r => exact r
| Or.inr (Or.inl r) =>
rw [r] at hx
apply Or.elim hx
· intro nx
simp at nx
· intro nx
simp only [Set.mem_singleton_iff] at nx
rw [nx] at hn
exact absurd hn hp.left.right
| Or.inr (Or.inr r) =>
apply Or.elim hx
· intro ⟨h₁, h₂⟩
have h₃ := subset_of_ssubset hC h₁
simp only [Set.mem_singleton_iff, Set.mem_Iio] at h₂ h₃
exact Or.elim (Nat.lt_or_eq_of_lt h₃) id (absurd · h₂)
· intro h
simp only [Set.mem_singleton_iff] at h
have := hp.left.left
rw [← h] at this
exact Or.elim (Nat.lt_or_eq_of_lt this)
id (absurd · (Nat.ne_of_lt r).symm)
have ⟨m, hm₁, hm₂⟩ := h_subset_equinumerous C' hC'₁
suffices C' ≈ C from
⟨m, hm₁, Set.equinumerous_trans (Set.equinumerous_symm this) hm₂⟩
-- Proves `f` is a one-to-one correspondence between `C'` and `C`.
let f x := if x = p then n else x
refine ⟨f, ?_, ?_, ?_⟩
· -- `Set.MapsTo f C' C`
intro x hx
dsimp only
by_cases hxp : x = p
· rw [if_pos hxp]
exact hn
· rw [if_neg hxp]
apply Or.elim hx
· exact fun x => x.left
· intro hx₁
simp only [Set.mem_singleton_iff] at hx₁
exact absurd hx₁ hxp
· -- `Set.InjOn f C'`
intro x₁ hx₁ x₂ hx₂ hf
dsimp only at hf
by_cases hx₁p : x₁ = p
· by_cases hx₂p : x₂ = p
· rw [hx₁p, hx₂p]
· rw [if_pos hx₁p, if_neg hx₂p] at hf
apply Or.elim hx₂
· intro nx
exact absurd hf.symm nx.right
· intro nx
simp only [Set.mem_singleton_iff] at nx
exact absurd nx hx₂p
· by_cases hx₂p : x₂ = p
· rw [if_neg hx₁p, if_pos hx₂p] at hf
apply Or.elim hx₁
· intro nx
exact absurd hf nx.right
· intro nx
simp only [Set.mem_singleton_iff] at nx
exact absurd nx hx₁p
· rwa [if_neg hx₁p, if_neg hx₂p] at hf
· -- `Set.SurjOn f C' C`
show ∀ x, x ∈ C → x ∈ f '' C'
intro x hx
simp only [
Set.union_singleton,
Set.mem_diff,
Set.mem_singleton_iff,
Set.mem_image,
Set.mem_insert_iff,
exists_eq_or_imp,
ite_true
]
by_cases nx₁ : x = n
· left
exact nx₁.symm
· right
by_cases nx₂ : x = p
· have := hp.left.right
rw [← nx₂] at this
exact absurd hx this
· exact ⟨x, ⟨hx, nx₁⟩, by rwa [if_neg]⟩
· refine h_subset_equinumerous C ?_
show ∀ x, x ∈ C → x ∈ Set.Iio n
intro x hx
unfold Set.Iio
apply Or.elim (Nat.lt_or_eq_of_lt (subset_of_ssubset hC hx))
· exact id
· intro hx₁
rw [hx₁] at hx
exact absurd hx hn
/-- #### Corollary 6G
Any subset of a finite set is finite.
-/
theorem corollary_6g {S S' : Set α} (hS : Set.Finite S) (hS' : S' ⊆ S)
: Set.Finite S' := by
rw [subset_iff_ssubset_or_eq] at hS'
apply Or.elim hS'
· intro h
rw [Set.finite_iff_equinumerous_nat] at hS
have ⟨n, F, hF⟩ := hS
-- Mirrors logic found in `corollary_6c`.
let T := S \ S'
let R := (Set.Iio n) \ (F '' T)
have hR : R ⊂ Set.Iio n := by
rw [Set.ssubset_def]
apply And.intro
· show ∀ x, x ∈ R → x ∈ Set.Iio n
intro _ hx
exact hx.left
· show ¬ ∀ x, x ∈ Set.Iio n → x ∈ R
intro nr
have ⟨t, ht₁⟩ : Set.Nonempty T := Set.diff_ssubset_nonempty h
have ht₂ : F t ∈ Set.Iio n := hF.left ht₁.left
have ht₃ : F t ∈ R := nr (F t) ht₂
exact absurd ⟨t, ht₁, rfl⟩ ht₃.right
suffices Set.BijOn F S' R by
have ⟨m, hm⟩ := lemma_6f hR
have := Set.equinumerous_trans ⟨F, this⟩ hm.right
exact Set.finite_iff_equinumerous_nat.mpr ⟨m, this⟩
refine ⟨?_, ?_, ?_⟩
· -- `Set.MapsTo f S' R`
intro x hx
dsimp only
simp only [Set.mem_diff, Set.mem_Iio, Set.mem_image, not_exists, not_and]
apply And.intro
· exact hF.left (subset_of_ssubset h hx)
· intro y hy
by_contra nf
have := hF.right.left (subset_of_ssubset h hx) hy.left nf.symm
rw [this] at hx
exact absurd hx hy.right
· -- `Set.InjOn f S'`
intro x₁ hx₁ x₂ hx₂ hf
have h₁ : x₁ ∈ S := subset_of_ssubset h hx₁
have h₂ : x₂ ∈ S := subset_of_ssubset h hx₂
exact hF.right.left h₁ h₂ hf
· -- `Set.SurjOn f S' R`
show ∀ x, x ∈ R → x ∈ F '' S'
intro x hx
have h₁ := hF.right.right
unfold Set.SurjOn at h₁
rw [Set.subset_def] at h₁
have ⟨y, hy⟩ := h₁ x hx.left
refine ⟨y, ?_, hy.right⟩
rw [← hy.right] at hx
simp only [Set.mem_image, Set.mem_diff, not_exists, not_and] at hx
by_contra ny
exact (hx.right y ⟨hy.left, ny⟩) rfl
· intro h
rwa [h]
/-- #### Exercise 6.1

2
Common/Set.lean
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@ -1,2 +1,4 @@
import Common.Set.Basic
import Common.Set.Equinumerous
import Common.Set.Intervals
import Common.Set.Peano

18
Common/Set/Basic.lean
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@ -175,6 +175,24 @@ theorem diff_ssubset_diff_left {A B : Set α} (h : A ⊂ B)
rw [diff_subset_iff, union_diff_cancel this] at nh
exact LT.lt.false (Set.ssubset_of_ssubset_of_subset h nh)
/--
For any sets `A ⊂ B`, `B \ A` is nonempty.
-/
theorem diff_ssubset_nonempty {A B : Set α} (h : A ⊂ B)
: Set.Nonempty (B \ A) := by
have : B = A (B \ A) := by
simp only [Set.union_diff_self]
exact (Set.left_subset_union_eq_self (subset_of_ssubset h)).symm
rw [this, Set.ssubset_def] at h
have : ¬ ∀ x, x ∈ A (B \ A) → x ∈ A := h.right
simp only [Set.mem_union, not_forall, exists_prop] at this
have ⟨x, hx⟩ := this
apply Or.elim hx.left
· intro nx
exact absurd nx hx.right
· intro hx
exact ⟨x, hx⟩
/--
For any set `A`, the difference between the sample space and `A` is the
complement of `A`.

86
Common/Set/Equinumerous.lean Normal file
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@ -0,0 +1,86 @@
import Mathlib.Data.Finset.Card
import Mathlib.Data.Set.Finite
/-! # Common.Set.Finite
Additional theorems around finite sets.
-/
namespace Set
/--
A set `A` is equinumerous to a set `B` (written `A ≈ B`) if and only if there is
a one-to-one function from `A` onto `B`.
-/
def Equinumerous (A : Set α) (B : Set β) : Prop := ∃ F, Set.BijOn F A B
infix:50 " ≈ " => Equinumerous
theorem equinumerous_def (A : Set α) (B : Set β)
: A ≈ B ↔ ∃ F, Set.BijOn F A B := Iff.rfl
/--
For any set `A`, `A ≈ A`.
-/
theorem equinumerous_refl (A : Set α)
: A ≈ A := by
refine ⟨fun x => x, ?_⟩
unfold Set.BijOn Set.MapsTo Set.InjOn Set.SurjOn
simp only [imp_self, implies_true, Set.image_id', true_and]
exact Eq.subset rfl
/--
For any sets `A` and `B`, if `A ≈ B`. then `B ≈ A`.
-/
theorem equinumerous_symm [Nonempty α] {A : Set α} {B : Set β}
(h : A ≈ B) : B ≈ A := by
have ⟨F, hF⟩ := h
refine ⟨Function.invFunOn F A, ?_⟩
exact (Set.bijOn_comm $ Set.BijOn.invOn_invFunOn hF).mpr hF
/--
For any sets `A`, `B`, and `C`, if `A ≈ B` and `B ≈ C`, then `A ≈ C`.
-/
theorem equinumerous_trans {A : Set α} {B : Set β} {C : Set γ}
(h₁ : A ≈ B) (h₂ : B ≈ C)
: ∃ H, Set.BijOn H A C := by
have ⟨F, hF⟩ := h₁
have ⟨G, hG⟩ := h₂
exact ⟨G ∘ F, Set.BijOn.comp hG hF⟩
/--
If two sets are equal, they are trivially equinumerous.
-/
theorem eq_imp_equinumerous {A B : Set α} (h : A = B)
: A ≈ B := by
have := equinumerous_refl A
conv at this => right; rw [h]
exact this
/--
A set is finite if and only if it is equinumerous to a natural number.
-/
axiom finite_iff_equinumerous_nat {α : Type _} {S : Set α}
: Set.Finite S ↔ ∃ n : , S ≈ Set.Iio n
/--
A set `A` is not equinumerous to a set `B` (written `A ≉ B`) if and only if
there is no one-to-one function from `A` onto `B`.
-/
def NotEquinumerous (A : Set α) (B : Set β) : Prop := ¬ Equinumerous A B
infix:50 " ≉ " => NotEquinumerous
@[simp]
theorem not_equinumerous_def : A ≉ B ↔ ∀ F, ¬ Set.BijOn F A B := by
apply Iff.intro
· intro h
unfold NotEquinumerous Equinumerous at h
simp only [not_exists] at h
exact h
· intro h
unfold NotEquinumerous Equinumerous
simp only [not_exists]
exact h
end Set

45
Common/Set/Finite.lean
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@ -1,45 +0,0 @@
import Mathlib.Data.Finset.Card
import Mathlib.Data.Set.Finite
/-! # Common.Set.Finite
Additional theorems around finite sets.
-/
namespace Set
/--
For any set `A`, `A ≈ A`.
-/
theorem equinumerous_refl (A : Set α)
: ∃ F, Set.BijOn F A A := by
refine ⟨fun x => x, ?_⟩
unfold Set.BijOn Set.MapsTo Set.InjOn Set.SurjOn
simp only [imp_self, implies_true, Set.image_id', true_and]
exact Eq.subset rfl
/--
For any sets `A` and `B`, if `A ≈ B`. then `B ≈ A`.
-/
theorem equinumerous_symm [Nonempty α] {A : Set α} {B : Set β}
{F : α → β} (hF : Set.BijOn F A B)
: ∃ G, Set.BijOn G B A := by
refine ⟨Function.invFunOn F A, ?_⟩
exact (Set.bijOn_comm $ Set.BijOn.invOn_invFunOn hF).mpr hF
/--
For any sets `A`, `B`, and `C`, if `A ≈ B` and `B ≈ C`, then `A ≈ C`.
-/
theorem equinumerous_trans {A : Set α} {B : Set β} {C : Set γ}
{F : α → β} (hF : Set.BijOn F A B)
{G : β → γ} (hG : Set.BijOn G B C)
: ∃ H, Set.BijOn H A C := by
exact ⟨G ∘ F, Set.BijOn.comp hG hF⟩
/--
A set is finite if and only if it is equinumerous to a natural number.
-/
axiom finite_iff_equinumerous_nat {α : Type _} {S : Set α}
: Set.Finite S ↔ ∃ n : , ∃ f, Set.BijOn f S (Set.Iio n)
end Set

25
Common/Set/Intervals.lean Normal file
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@ -0,0 +1,25 @@
import Common.Logic.Basic
import Mathlib.Data.Set.Intervals.Basic
namespace Set
/-! # Common.Set.Intervals
Additional theorems around intervals.
-/
theorem Iio_nat_lt_ssubset {m n : } (h : m < n)
: Iio m ⊂ Iio n := by
rw [ssubset_def]
apply And.intro
· unfold Iio
simp only [setOf_subset_setOf]
intro x hx
calc x
_ < m := hx
_ < n := h
· show ¬ ∀ x, x < n → x < m
simp only [not_forall, not_lt, exists_prop]
exact ⟨m, h, by simp⟩
end Set