263 lines
6.6 KiB
Plaintext
263 lines
6.6 KiB
Plaintext
import Common.Logic.Basic
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import Mathlib.Data.Set.Basic
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import Mathlib.Data.Set.Prod
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/-! # Common.Set.Basic
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Additional theorems and definitions useful in the context of `Set`s.
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-/
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namespace Set
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/-! ## Minkowski Sum -/
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/-
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The Minkowski sum of two `Set`s `s` and `t` is the set
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`s + t = { a + b : a ∈ s, b ∈ t }`.
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-/
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def minkowskiSum {α : Type u} [Add α] (s t : Set α) :=
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{ x | ∃ a ∈ s, ∃ b ∈ t, x = a + b }
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/--
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The sum of two `Set`s is nonempty **iff** the summands are nonempty.
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-/
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theorem nonempty_minkowski_sum_iff_nonempty_add_nonempty {α : Type u} [Add α]
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{s t : Set α}
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: (minkowskiSum s t).Nonempty ↔ s.Nonempty ∧ t.Nonempty := by
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apply Iff.intro
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· intro h
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have ⟨x, hx⟩ := h
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have ⟨a, ⟨ha, ⟨b, ⟨hb, _⟩⟩⟩⟩ := hx
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apply And.intro
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· exact ⟨a, ha⟩
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· exact ⟨b, hb⟩
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· intro ⟨⟨a, ha⟩, ⟨b, hb⟩⟩
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exact ⟨a + b, ⟨a, ⟨ha, ⟨b, ⟨hb, rfl⟩⟩⟩⟩⟩
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/-! ## Pair Sets -/
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/--
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If `{x, y} = {x}` then `x = y`.
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-/
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theorem pair_eq_singleton_mem_imp_eq_self {x y : α}
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(h : {x, y} = ({x} : Set α)) : y = x := by
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rw [Set.ext_iff] at h
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have := h y
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simp at this
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exact this
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/--
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If `{x, y} = {z}` then `x = y = z`.
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-/
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theorem pair_eq_singleton_mem_imp_eq_all {x y z : α}
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(h : {x, y} = ({z} : Set α)) : x = z ∧ y = z := by
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have h' := h
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rw [Set.ext_iff] at h'
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have hz := h' z
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simp at hz
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apply Or.elim hz
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· intro hzx
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rw [← hzx] at h
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have := pair_eq_singleton_mem_imp_eq_self h
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exact ⟨hzx.symm, this⟩
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· intro hzy
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rw [← hzy, Set.pair_comm] at h
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have := pair_eq_singleton_mem_imp_eq_self h
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exact ⟨this, hzy.symm⟩
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/-! ## Subsets -/
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/--
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Every `Set` is a subset of itself.
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-/
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theorem subset_self (S : Set α) : S ⊆ S := by
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intro _ hs
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exact hs
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/--
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If `Set` `A` is a subset of `Set` `B`, then `A ∪ B = B`.
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-/
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theorem left_subset_union_eq_self {A B : Set α} (h : A ⊆ B)
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: A ∪ B = B := by
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rw [Set.ext_iff]
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intro x
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apply Iff.intro
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· intro hU
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apply Or.elim hU
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· intro hA
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exact h hA
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· simp
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· intro hB
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exact Or.inr hB
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/--
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If `Set` `B` is a subset of `Set` `A`, then `A ∪ B = B`.
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-/
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theorem right_subset_union_eq_self {A B : Set α} (h : B ⊆ A)
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: A ∪ B = A := by
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rw [Set.union_comm]
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exact left_subset_union_eq_self h
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/--
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If `x` and `y` are members of `Set` `A`, it follows `{x, y}` is a subset of `A`.
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-/
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theorem mem_mem_imp_pair_subset {x y : α}
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(hx : x ∈ A) (hy : y ∈ A) : ({x, y} : Set α) ⊆ A := by
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intro a ha
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apply Or.elim ha
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· intro hx'
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rwa [hx']
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· intro hy'
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rwa [hy']
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/-! ## Powerset -/
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/--
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Every `Set` is a member of its own powerset.
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-/
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theorem self_mem_powerset_self {A : Set α}
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: A ∈ 𝒫 A := subset_self A
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/-! ## Cartesian Product -/
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/--
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For any `Set` `A`, `∅ × A = ∅`.
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-/
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theorem prod_left_emptyset_eq_emptyset {A : Set α}
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: Set.prod (∅ : Set β) A = ∅ := by
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unfold prod
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simp only [mem_empty_iff_false, false_and, setOf_false]
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/--
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For any `Set` `A`, `A × ∅ = ∅`.
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-/
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theorem prod_right_emptyset_eq_emptyset {A : Set α}
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: Set.prod A (∅ : Set β) = ∅ := by
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unfold prod
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simp only [mem_empty_iff_false, and_false, setOf_false]
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/--
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For any `Set`s `A` and `B`, if both `A` and `B` are nonempty, then `A × B` is
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also nonempty.
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-/
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theorem prod_nonempty_nonempty_imp_nonempty_prod {A : Set α} {B : Set β}
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: A ≠ ∅ ∧ B ≠ ∅ ↔ Set.prod A B ≠ ∅ := by
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apply Iff.intro
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· intro nAB h
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have ⟨a, ha⟩ := nonempty_iff_ne_empty.mpr nAB.left
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have ⟨b, hb⟩ := nonempty_iff_ne_empty.mpr nAB.right
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rw [Set.ext_iff] at h
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exact (h (a, b)).mp ⟨ha, hb⟩
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· intro h
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rw [← nonempty_iff_ne_empty] at h
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have ⟨(a, b), ⟨ha, hb⟩⟩ := h
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rw [← nonempty_iff_ne_empty, ← nonempty_iff_ne_empty]
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exact ⟨⟨a, ha⟩, ⟨b, hb⟩⟩
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/-! ## Difference -/
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/--
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For any set `A`, the difference between the sample space and `A` is the
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complement of `A`.
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-/
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theorem univ_diff_self_eq_compl (A : Set α) : Set.univ \ A = A.compl := by
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unfold Set.compl SDiff.sdiff instSDiffSet Set.diff
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simp only [mem_univ, true_and]
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/--
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For any set `A`, the difference between the sample space and the complement of
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`A` is `A`.
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-/
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theorem univ_diff_compl_eq_self (A : Set α) : Set.univ \ A.compl = A := by
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unfold Set.compl SDiff.sdiff instSDiffSet Set.diff
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simp only [mem_univ, mem_setOf_eq, not_not, true_and, setOf_mem_eq]
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/-! ## Symmetric Difference -/
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/--
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If `x ∈ A` and `x ∉ B`, then `x ∈ A ∆ B`.
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-/
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theorem symm_diff_mem_left {A B : Set α} (hA : x ∈ A) (hB : x ∉ B)
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: x ∈ A ∆ B := by
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left
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exact ⟨hA, hB⟩
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/--
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If `x ∉ A` and `x ∈ B`, then `x ∈ A ∆ B`.
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-/
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theorem symm_diff_mem_right {A B : Set α} (hA : x ∉ A) (hB : x ∈ B)
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: x ∈ A ∆ B := by
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right
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exact ⟨hB, hA⟩
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/--
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If `x ∈ A` and `x ∈ B`, then `x ∉ A ∆ B`.
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-/
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theorem symm_diff_mem_both_not_mem {A B : Set α} (hA : x ∈ A) (hB : x ∈ B)
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: x ∉ A ∆ B := by
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intro h
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apply Or.elim h
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· intro ⟨_, nB⟩
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exact absurd hB nB
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· intro ⟨_, nA⟩
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exact absurd hA nA
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/--
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If `x ∉ A` and `x ∉ B`, then `x ∉ A ∆ B`.
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-/
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theorem symm_diff_not_mem_both_not_mem {A B : Set α} (nA : x ∉ A) (nB : x ∉ B)
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: x ∉ A ∆ B := by
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intro h
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apply Or.elim h
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· intro ⟨hA, _⟩
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exact absurd hA nA
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· intro ⟨hB, _⟩
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exact absurd hB nB
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/--
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`x` is a member of the `symmDiff` of `A` and `B` **iff** `x ∈ A ∧ x ∉ B` or
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`x ∉ A ∧ x ∈ B`.
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-/
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theorem mem_symm_diff_iff_exclusive_mem {A B : Set α}
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: x ∈ (A ∆ B) ↔ (x ∈ A ∧ x ∉ B) ∨ (x ∉ A ∧ x ∈ B) := by
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unfold symmDiff
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apply Iff.intro
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· intro hx
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simp at hx
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conv => arg 2; rw [and_comm]
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exact hx
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· intro hx
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simp
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conv => arg 2; rw [and_comm]
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exact hx
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/--
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`x` is not a member of the `symmDiff` of `A` and `B` **iff** `x ∈ A ∩ B` or
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`x ∉ A ∪ B`.
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This is the contraposition of `mem_symm_diff_iff_exclusive_mem`.
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-/
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theorem not_mem_symm_diff_inter_or_not_union {A B : Set α}
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: x ∉ (A ∆ B) ↔ (x ∈ A ∩ B) ∨ (x ∉ A ∪ B) := by
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show ¬(x ∈ A ∧ ¬x ∈ B ∨ x ∈ B ∧ ¬x ∈ A) ↔ x ∈ A ∧ x ∈ B ∨ ¬(x ∈ A ∨ x ∈ B)
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rw [
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not_or_de_morgan,
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not_and_de_morgan, not_and_de_morgan,
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not_not, not_not,
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not_or_de_morgan
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]
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apply Iff.intro
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· intro nx
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apply Or.elim nx.left
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· intro nA
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exact Or.elim nx.right (Or.inr ⟨nA, ·⟩) (absurd · nA)
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· intro hB
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exact Or.elim nx.right (absurd hB ·) (Or.inl ⟨·, hB⟩)
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· intro hx
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apply Or.elim hx
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· intro hy
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exact ⟨Or.inr hy.right, Or.inr hy.left⟩
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· intro hy
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exact ⟨Or.inl hy.left, Or.inl hy.right⟩
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end Set |