99 lines
4.2 KiB
Text
99 lines
4.2 KiB
Text
/-
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Copyright (c) 2015 Microsoft Corporation. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Author: Jeremy Avigad
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Finite unions and intersections on finsets.
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Note: for the moment we only do unions. We need to generalize bigops for intersections.
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-/
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import data.finset.comb algebra.group_bigops
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open list
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namespace finset
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variables {A B : Type} [deceqA : decidable_eq A] [deceqB : decidable_eq B]
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/- Unionl and Union -/
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section union
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definition to_comm_monoid_Union (B : Type) [deceqB : decidable_eq B] :
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algebra.comm_monoid (finset B) :=
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⦃ algebra.comm_monoid,
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mul := union,
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mul_assoc := union.assoc,
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one := empty,
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mul_one := union_empty,
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one_mul := empty_union,
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mul_comm := union.comm
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⦄
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open [classes] algebra
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local attribute finset.to_comm_monoid_Union [instance]
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include deceqB
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definition Unionl (l : list A) (f : A → finset B) : finset B := algebra.Prodl l f
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notation `⋃` binders `←` l, r:(scoped f, Unionl l f) := r
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definition Union (s : finset A) (f : A → finset B) : finset B := algebra.Prod s f
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notation `⋃` binders `∈` s, r:(scoped f, finset.Union s f) := r
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theorem Unionl_nil (f : A → finset B) : Unionl [] f = ∅ := algebra.Prodl_nil f
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theorem Unionl_cons (f : A → finset B) (a : A) (l : list A) :
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Unionl (a::l) f = f a ∪ Unionl l f := algebra.Prodl_cons f a l
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theorem Unionl_append (l₁ l₂ : list A) (f : A → finset B) :
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Unionl (l₁++l₂) f = Unionl l₁ f ∪ Unionl l₂ f := algebra.Prodl_append l₁ l₂ f
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theorem Unionl_mul (l : list A) (f g : A → finset B) :
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Unionl l (λx, f x ∪ g x) = Unionl l f ∪ Unionl l g := algebra.Prodl_mul l f g
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section deceqA
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include deceqA
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theorem Unionl_insert_of_mem (f : A → finset B) {a : A} {l : list A} (H : a ∈ l) :
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Unionl (list.insert a l) f = Unionl l f := algebra.Prodl_insert_of_mem f H
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theorem Unionl_insert_of_not_mem (f : A → finset B) {a : A} {l : list A} (H : a ∉ l) :
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Unionl (list.insert a l) f = f a ∪ Unionl l f := algebra.Prodl_insert_of_not_mem f H
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theorem Unionl_union {l₁ l₂ : list A} (f : A → finset B) (d : list.disjoint l₁ l₂) :
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Unionl (list.union l₁ l₂) f = Unionl l₁ f ∪ Unionl l₂ f := algebra.Prodl_union f d
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theorem Unionl_empty (l : list A) : Unionl l (λ x, ∅) = (∅ : finset B) := algebra.Prodl_one l
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end deceqA
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theorem Union_empty (f : A → finset B) : Union ∅ f = ∅ := algebra.Prod_empty f
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theorem Union_mul (s : finset A) (f g : A → finset B) :
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Union s (λx, f x ∪ g x) = Union s f ∪ Union s g := algebra.Prod_mul s f g
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section deceqA
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include deceqA
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theorem Union_insert_of_mem (f : A → finset B) {a : A} {s : finset A} (H : a ∈ s) :
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Union (insert a s) f = Union s f := algebra.Prod_insert_of_mem f H
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theorem Union_insert_of_not_mem (f : A → finset B) {a : A} {s : finset A} (H : a ∉ s) :
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Union (insert a s) f = f a ∪ Union s f := algebra.Prod_insert_of_not_mem f H
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theorem Union_union (f : A → finset B) {s₁ s₂ : finset A} (disj : s₁ ∩ s₂ = ∅) :
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Union (s₁ ∪ s₂) f = Union s₁ f ∪ Union s₂ f := algebra.Prod_union f disj
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theorem Union_ext {s : finset A} {f g : A → finset B} (H : ∀x, x ∈ s → f x = g x) :
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Union s f = Union s g := algebra.Prod_ext H
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theorem Union_empty' (s : finset A) : Union s (λ x, ∅) = (∅ : finset B) := algebra.Prod_one s
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-- this will eventually be an instance of something more general
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theorem inter_Union (s : finset B) (t : finset A) (f : A → finset B) :
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s ∩ (⋃ x ∈ t, f x) = (⋃ x ∈ t, s ∩ f x) :=
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begin
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induction t with s' x H IH,
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rewrite [*Union_empty, inter_empty],
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rewrite [*Union_insert_of_not_mem _ H, inter.distrib_left, IH],
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end
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theorem mem_Union_iff (s : finset A) (f : A → finset B) (b : B) :
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b ∈ (⋃ x ∈ s, f x) ↔ (∃ x, x ∈ s ∧ b ∈ f x ) :=
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begin
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induction s with s' a H IH,
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rewrite [exists_mem_empty_eq],
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rewrite [Union_insert_of_not_mem _ H, mem_union_eq, IH, exists_mem_insert_eq]
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end
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theorem mem_Union_eq (s : finset A) (f : A → finset B) (b : B) :
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b ∈ (⋃ x ∈ s, f x) = (∃ x, x ∈ s ∧ b ∈ f x ) :=
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propext !mem_Union_iff
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end deceqA
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end union
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end finset
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