lean2/library/data/bag.lean

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/-
Copyright (c) 2015 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Leonardo de Moura
Finite bags.
-/
import data.nat data.list.perm algebra.binary
open nat quot list subtype binary function eq.ops
open [declarations] perm
open algebra
variable {A : Type}
definition bag.setoid [instance] (A : Type) : setoid (list A) :=
setoid.mk (@perm A) (mk_equivalence (@perm A) (@perm.refl A) (@perm.symm A) (@perm.trans A))
definition bag (A : Type) : Type :=
quot (bag.setoid A)
namespace bag
definition of_list (l : list A) : bag A :=
⟦l⟧
definition empty : bag A :=
of_list nil
definition singleton (a : A) : bag A :=
of_list [a]
definition insert (a : A) (b : bag A) : bag A :=
quot.lift_on b (λ l, ⟦a::l⟧)
(λ l₁ l₂ h, quot.sound (perm.skip a h))
lemma insert_empty_eq_singleton (a : A) : insert a empty = singleton a :=
rfl
definition insert.comm (a₁ a₂ : A) (b : bag A) : insert a₁ (insert a₂ b) = insert a₂ (insert a₁ b) :=
quot.induction_on b (λ l, quot.sound !perm.swap)
definition append (b₁ b₂ : bag A) : bag A :=
quot.lift_on₂ b₁ b₂ (λ l₁ l₂, ⟦l₁++l₂⟧)
(λ l₁ l₂ l₃ l₄ h₁ h₂, quot.sound (perm_app h₁ h₂))
infix ++ := append
lemma append.comm (b₁ b₂ : bag A) : b₁ ++ b₂ = b₂ ++ b₁ :=
quot.induction_on₂ b₁ b₂ (λ l₁ l₂, quot.sound !perm_app_comm)
lemma append.assoc (b₁ b₂ b₃ : bag A) : (b₁ ++ b₂) ++ b₃ = b₁ ++ (b₂ ++ b₃) :=
quot.induction_on₃ b₁ b₂ b₃ (λ l₁ l₂ l₃, quot.sound (by rewrite list.append.assoc; apply perm.refl))
lemma append_empty_left (b : bag A) : empty ++ b = b :=
quot.induction_on b (λ l, quot.sound (by rewrite append_nil_left; apply perm.refl))
lemma append_empty_right (b : bag A) : b ++ empty = b :=
quot.induction_on b (λ l, quot.sound (by rewrite append_nil_right; apply perm.refl))
lemma append_insert_left (a : A) (b₁ b₂ : bag A) : insert a b₁ ++ b₂ = insert a (b₁ ++ b₂) :=
quot.induction_on₂ b₁ b₂ (λ l₁ l₂, quot.sound (by rewrite append_cons; apply perm.refl))
lemma append_insert_right (a : A) (b₁ b₂ : bag A) : b₁ ++ insert a b₂ = insert a (b₁ ++ b₂) :=
calc b₁ ++ insert a b₂ = insert a b₂ ++ b₁ : append.comm
... = insert a (b₂ ++ b₁) : append_insert_left
... = insert a (b₁ ++ b₂) : append.comm
protected lemma induction_on [recursor 3] {C : bag A → Prop} (b : bag A) (h₁ : C empty) (h₂ : ∀ a b, C b → C (insert a b)) : C b :=
quot.induction_on b (λ l, list.induction_on l h₁ (λ h t ih, h₂ h ⟦t⟧ ih))
section decidable_eq
variable [decA : decidable_eq A]
include decA
open decidable
definition has_decidable_eq [instance] (b₁ b₂ : bag A) : decidable (b₁ = b₂) :=
quot.rec_on_subsingleton₂ b₁ b₂ (λ l₁ l₂,
match decidable_perm l₁ l₂ with
| inl h := inl (quot.sound h)
| inr h := inr (λ n, absurd (quot.exact n) h)
end)
end decidable_eq
section count
variable [decA : decidable_eq A]
include decA
definition count (a : A) (b : bag A) : nat :=
quot.lift_on b (λ l, count a l)
(λ l₁ l₂ h, count_eq_of_perm h a)
lemma count_empty (a : A) : count a empty = 0 :=
rfl
lemma count_insert (a : A) (b : bag A) : count a (insert a b) = succ (count a b) :=
quot.induction_on b (λ l, begin unfold [insert, count], rewrite count_cons_eq end)
lemma count_insert_of_ne {a₁ a₂ : A} (h : a₁ ≠ a₂) (b : bag A) : count a₁ (insert a₂ b) = count a₁ b :=
quot.induction_on b (λ l, begin unfold [insert, count], rewrite (count_cons_of_ne h) end)
lemma count_singleton (a : A) : count a (singleton a) = 1 :=
begin rewrite [-insert_empty_eq_singleton, count_insert] end
lemma count_append (a : A) (b₁ b₂ : bag A) : count a (append b₁ b₂) = count a b₁ + count a b₂ :=
quot.induction_on₂ b₁ b₂ (λ l₁ l₂, begin unfold [append, count], rewrite list.count_append end)
open perm decidable
protected lemma ext {b₁ b₂ : bag A} : (∀ a, count a b₁ = count a b₂) → b₁ = b₂ :=
quot.induction_on₂ b₁ b₂ (λ l₁ l₂ (h : ∀ a, count a ⟦l₁⟧ = count a ⟦l₂⟧),
have gen : ∀ (l₁ l₂ : list A), (∀ a, list.count a l₁ = list.count a l₂) → l₁ ~ l₂
| [] [] h₁ := !perm.refl
| [] (a₂::s₂) h₁ := assert list.count a₂ [] = list.count a₂ (a₂::s₂), from h₁ a₂, by rewrite [count_nil at this, count_cons_eq at this]; contradiction
| (a::s₁) s₂ h₁ :=
assert g₁ : list.count a (a::s₁) > 0, from count_gt_zero_of_mem !mem_cons,
assert list.count a (a::s₁) = list.count a s₂, from h₁ a,
assert list.count a s₂ > 0, by rewrite [-this]; exact g₁,
have a ∈ s₂, from mem_of_count_gt_zero this,
have ∃ l r, s₂ = l++(a::r), from mem_split this,
obtain l r (e₁ : s₂ = l++(a::r)), from this,
have ∀ a, list.count a s₁ = list.count a (l++r), from
take a₁,
assert e₂ : list.count a₁ (a::s₁) = list.count a₁ (l++(a::r)), by rewrite -e₁; exact h₁ a₁,
by_cases
(suppose a₁ = a, begin
rewrite [-this at e₂, list.count_append at e₂, *count_cons_eq at e₂, add_succ at e₂],
injection e₂ with e₃, rewrite e₃,
rewrite list.count_append
end)
(suppose a₁ ≠ a,
by rewrite [list.count_append at e₂, *count_cons_of_ne this at e₂, e₂, list.count_append]),
have ih : s₁ ~ l++r, from gen s₁ (l++r) this,
calc a::s₁ ~ a::(l++r) : perm.skip a ih
... ~ l++(a::r) : perm_middle
... = s₂ : e₁,
quot.sound (gen l₁ l₂ h))
definition insert.inj {a : A} {b₁ b₂ : bag A} : insert a b₁ = insert a b₂ → b₁ = b₂ :=
assume h, bag.ext (take x,
assert e : count x (insert a b₁) = count x (insert a b₂), by rewrite h,
by_cases
(suppose x = a, begin subst x, rewrite [*count_insert at e], injection e, assumption end)
(suppose x ≠ a, begin rewrite [*count_insert_of_ne this at e], assumption end))
end count
section extract
open decidable
variable [decA : decidable_eq A]
include decA
definition extract (a : A) (b : bag A) : bag A :=
quot.lift_on b (λ l, ⟦filter (λ c, c ≠ a) l⟧)
(λ l₁ l₂ h, quot.sound (perm_filter h))
lemma extract_singleton (a : A) : extract a (singleton a) = empty :=
begin unfold [extract, singleton, of_list, filter], rewrite [if_neg (λ h : a ≠ a, absurd rfl h)] end
lemma extract_insert (a : A) (b : bag A) : extract a (insert a b) = extract a b :=
quot.induction_on b (λ l, begin
unfold [insert, extract],
rewrite [@filter_cons_of_neg _ (λ c, c ≠ a) _ _ l (not_not_intro (eq.refl a))]
end)
lemma extract_insert_of_ne {a₁ a₂ : A} (h : a₁ ≠ a₂) (b : bag A) : extract a₁ (insert a₂ b) = insert a₂ (extract a₁ b) :=
quot.induction_on b (λ l, begin
unfold [insert, extract],
rewrite [@filter_cons_of_pos _ (λ c, c ≠ a₁) _ _ l (ne.symm h)]
end)
lemma count_extract (a : A) (b : bag A) : count a (extract a b) = 0 :=
bag.induction_on b rfl
(λ c b ih, by_cases
(suppose a = c, begin subst c, rewrite [extract_insert, ih] end)
(suppose a ≠ c, begin rewrite [extract_insert_of_ne this, count_insert_of_ne this, ih] end))
lemma count_extract_of_ne {a₁ a₂ : A} (h : a₁ ≠ a₂) (b : bag A) : count a₁ (extract a₂ b) = count a₁ b :=
bag.induction_on b rfl
(take x b ih, by_cases
(suppose x = a₁, begin subst x, rewrite [extract_insert_of_ne (ne.symm h), *count_insert, ih] end)
(suppose x ≠ a₁, by_cases
(suppose x = a₂, begin subst x, rewrite [extract_insert, ih, count_insert_of_ne h] end)
(suppose x ≠ a₂, begin
rewrite [count_insert_of_ne (ne.symm `x ≠ a₁`), extract_insert_of_ne (ne.symm this)],
rewrite [count_insert_of_ne (ne.symm `x ≠ a₁`), ih]
end)))
end extract
section erase
variable [decA : decidable_eq A]
include decA
definition erase (a : A) (b : bag A) : bag A :=
quot.lift_on b (λ l, ⟦erase a l⟧)
(λ l₁ l₂ h, quot.sound (erase_perm_erase_of_perm _ h))
lemma erase_empty (a : A) : erase a empty = empty :=
rfl
lemma erase_insert (a : A) (b : bag A) : erase a (insert a b) = b :=
quot.induction_on b (λ l, quot.sound (by rewrite erase_cons_head; apply perm.refl))
lemma erase_insert_of_ne {a₁ a₂ : A} (h : a₁ ≠ a₂) (b : bag A) : erase a₁ (insert a₂ b) = insert a₂ (erase a₁ b) :=
quot.induction_on b (λ l, quot.sound (by rewrite (erase_cons_tail _ h); apply perm.refl))
end erase
section member
variable [decA : decidable_eq A]
include decA
definition mem (a : A) (b : bag A) := count a b > 0
infix ∈ := mem
lemma mem_def (a : A) (b : bag A) : (a ∈ b) = (count a b > 0) :=
rfl
lemma mem_insert (a : A) (b : bag A) : a ∈ insert a b :=
begin unfold mem, rewrite count_insert, exact dec_trivial end
lemma mem_of_list_iff_mem (a : A) (l : list A) : a ∈ of_list l ↔ a ∈ l :=
iff.intro !mem_of_count_gt_zero !count_gt_zero_of_mem
lemma count_of_list_eq_count (a : A) (l : list A) : count a (of_list l) = list.count a l :=
rfl
end member
section union_inter
variable [decA : decidable_eq A]
include decA
open perm decidable
private definition union_list (l₁ l₂ : list A) :=
erase_dup (l₁ ++ l₂)
private lemma perm_union_list {l₁ l₂ l₃ l₄ : list A} (h₁ : l₁ ~ l₃) (h₂ : l₂ ~ l₄) : union_list l₁ l₂ ~ union_list l₃ l₄ :=
perm_erase_dup_of_perm (perm_app h₁ h₂)
private lemma nodup_union_list (l₁ l₂ : list A) : nodup (union_list l₁ l₂) :=
!nodup_erase_dup
private definition not_mem_of_not_mem_union_list_left {a : A} {l₁ l₂ : list A} (h : a ∉ union_list l₁ l₂) : a ∉ l₁ :=
suppose a ∈ l₁,
have a ∈ l₁ ++ l₂, from mem_append_left _ this,
have a ∈ erase_dup (l₁ ++ l₂), from mem_erase_dup this,
absurd this h
private definition not_mem_of_not_mem_union_list_right {a : A} {l₁ l₂ : list A} (h : a ∉ union_list l₁ l₂) : a ∉ l₂ :=
suppose a ∈ l₂,
have a ∈ l₁ ++ l₂, from mem_append_right _ this,
have a ∈ erase_dup (l₁ ++ l₂), from mem_erase_dup this,
absurd this h
private definition gen : nat → A → list A
| 0 a := nil
| (n+1) a := a :: gen n a
private lemma not_mem_gen_of_ne {a b : A} (h : a ≠ b) : ∀ n, a ∉ gen n b
| 0 := !not_mem_nil
| (n+1) := not_mem_cons_of_ne_of_not_mem h (not_mem_gen_of_ne n)
private lemma count_gen : ∀ (a : A) (n : nat), list.count a (gen n a) = n
| a 0 := rfl
| a (n+1) := begin unfold gen, rewrite [count_cons_eq, count_gen] end
private lemma count_gen_eq_zero_of_ne {a b : A} (h : a ≠ b) : ∀ n, list.count a (gen n b) = 0
| 0 := rfl
| (n+1) := begin unfold gen, rewrite [count_cons_of_ne h, count_gen_eq_zero_of_ne] end
private definition max_count (l₁ l₂ : list A) : list A → list A
| [] := []
| (a::l) := if list.count a l₁ ≥ list.count a l₂ then gen (list.count a l₁) a ++ max_count l else gen (list.count a l₂) a ++ max_count l
private definition min_count (l₁ l₂ : list A) : list A → list A
| [] := []
| (a::l) := if list.count a l₁ ≤ list.count a l₂ then gen (list.count a l₁) a ++ min_count l else gen (list.count a l₂) a ++ min_count l
private lemma not_mem_max_count_of_not_mem (l₁ l₂ : list A) : ∀ {a l}, a ∉ l → a ∉ max_count l₁ l₂ l
| a [] h := !not_mem_nil
| a (b::l) h :=
assert ih : a ∉ max_count l₁ l₂ l, from not_mem_max_count_of_not_mem (not_mem_of_not_mem_cons h),
assert a ≠ b, from ne_of_not_mem_cons h,
by_cases
(suppose list.count b l₁ ≥ list.count b l₂, begin
unfold max_count, rewrite [if_pos this],
exact not_mem_append (not_mem_gen_of_ne `a ≠ b` _) ih
end)
(suppose ¬ list.count b l₁ ≥ list.count b l₂, begin
unfold max_count, rewrite [if_neg this],
exact not_mem_append (not_mem_gen_of_ne `a ≠ b` _) ih
end)
private lemma max_count_eq (l₁ l₂ : list A) : ∀ {a : A} {l : list A}, a ∈ l → nodup l → list.count a (max_count l₁ l₂ l) = max (list.count a l₁) (list.count a l₂)
| a [] h₁ h₂ := absurd h₁ !not_mem_nil
| a (b::l) h₁ h₂ :=
assert nodup l, from nodup_of_nodup_cons h₂,
assert b ∉ l, from not_mem_of_nodup_cons h₂,
or.elim h₁
(suppose a = b,
have a ∉ l, by rewrite this; assumption,
assert a ∉ max_count l₁ l₂ l, from not_mem_max_count_of_not_mem l₁ l₂ this,
by_cases
(suppose i : list.count a l₁ ≥ list.count a l₂, begin
unfold max_count, subst b,
rewrite [if_pos i, list.count_append, count_gen, max_eq_left i, count_eq_zero_of_not_mem `a ∉ max_count l₁ l₂ l`]
end)
(suppose i : ¬ list.count a l₁ ≥ list.count a l₂, begin
unfold max_count, subst b,
rewrite [if_neg i, list.count_append, count_gen, max_eq_right_of_lt (lt_of_not_ge i), count_eq_zero_of_not_mem `a ∉ max_count l₁ l₂ l`]
end))
(suppose a ∈ l,
assert a ≠ b, from suppose a = b, by subst b; contradiction,
assert ih : list.count a (max_count l₁ l₂ l) = max (list.count a l₁) (list.count a l₂), from max_count_eq `a ∈ l` `nodup l`,
by_cases
(suppose i : list.count b l₁ ≥ list.count b l₂, begin
unfold max_count,
rewrite [if_pos i, -ih, list.count_append, count_gen_eq_zero_of_ne `a ≠ b`, zero_add]
end)
(suppose i : ¬ list.count b l₁ ≥ list.count b l₂, begin
unfold max_count,
rewrite [if_neg i, -ih, list.count_append, count_gen_eq_zero_of_ne `a ≠ b`, zero_add]
end))
private lemma not_mem_min_count_of_not_mem (l₁ l₂ : list A) : ∀ {a l}, a ∉ l → a ∉ min_count l₁ l₂ l
| a [] h := !not_mem_nil
| a (b::l) h :=
assert ih : a ∉ min_count l₁ l₂ l, from not_mem_min_count_of_not_mem (not_mem_of_not_mem_cons h),
assert a ≠ b, from ne_of_not_mem_cons h,
by_cases
(suppose list.count b l₁ ≤ list.count b l₂, begin
unfold min_count, rewrite [if_pos this],
exact not_mem_append (not_mem_gen_of_ne `a ≠ b` _) ih
end)
(suppose ¬ list.count b l₁ ≤ list.count b l₂, begin
unfold min_count, rewrite [if_neg this],
exact not_mem_append (not_mem_gen_of_ne `a ≠ b` _) ih
end)
private lemma min_count_eq (l₁ l₂ : list A) : ∀ {a : A} {l : list A}, a ∈ l → nodup l → list.count a (min_count l₁ l₂ l) = min (list.count a l₁) (list.count a l₂)
| a [] h₁ h₂ := absurd h₁ !not_mem_nil
| a (b::l) h₁ h₂ :=
assert nodup l, from nodup_of_nodup_cons h₂,
assert b ∉ l, from not_mem_of_nodup_cons h₂,
or.elim h₁
(suppose a = b,
have a ∉ l, by rewrite this; assumption,
assert a ∉ min_count l₁ l₂ l, from not_mem_min_count_of_not_mem l₁ l₂ this,
by_cases
(suppose i : list.count a l₁ ≤ list.count a l₂, begin
unfold min_count, subst b,
rewrite [if_pos i, list.count_append, count_gen, min_eq_left i, count_eq_zero_of_not_mem `a ∉ min_count l₁ l₂ l`]
end)
(suppose i : ¬ list.count a l₁ ≤ list.count a l₂, begin
unfold min_count, subst b,
rewrite [if_neg i, list.count_append, count_gen, min_eq_right (le_of_lt (lt_of_not_ge i)), count_eq_zero_of_not_mem `a ∉ min_count l₁ l₂ l`]
end))
(suppose a ∈ l,
assert a ≠ b, from suppose a = b, by subst b; contradiction,
assert ih : list.count a (min_count l₁ l₂ l) = min (list.count a l₁) (list.count a l₂), from min_count_eq `a ∈ l` `nodup l`,
by_cases
(suppose i : list.count b l₁ ≤ list.count b l₂, begin
unfold min_count,
rewrite [if_pos i, -ih, list.count_append, count_gen_eq_zero_of_ne `a ≠ b`, zero_add]
end)
(suppose i : ¬ list.count b l₁ ≤ list.count b l₂, begin
unfold min_count,
rewrite [if_neg i, -ih, list.count_append, count_gen_eq_zero_of_ne `a ≠ b`, zero_add]
end))
private lemma perm_max_count_left {l₁ l₂ l₃ l₄ : list A} (h₁ : l₁ ~ l₃) (h₂ : l₂ ~ l₄) : ∀ l, max_count l₁ l₂ l ~ max_count l₃ l₄ l
| [] := by esimp
| (a::l) :=
assert e₁ : list.count a l₁ = list.count a l₃, from count_eq_of_perm h₁ a,
assert e₂ : list.count a l₂ = list.count a l₄, from count_eq_of_perm h₂ a,
by_cases
(suppose list.count a l₁ ≥ list.count a l₂,
begin unfold max_count, rewrite [-e₁, -e₂, *if_pos this], exact perm_app !perm.refl !perm_max_count_left end)
(suppose ¬ list.count a l₁ ≥ list.count a l₂,
begin unfold max_count, rewrite [-e₁, -e₂, *if_neg this], exact perm_app !perm.refl !perm_max_count_left end)
private lemma perm_app_left_comm (l₁ l₂ l₃ : list A) : l₁ ++ (l₂ ++ l₃) ~ l₂ ++ (l₁ ++ l₃) :=
calc l₁ ++ (l₂ ++ l₃) = (l₁ ++ l₂) ++ l₃ : list.append.assoc
... ~ (l₂ ++ l₁) ++ l₃ : perm_app !perm_app_comm !perm.refl
... = l₂ ++ (l₁ ++ l₃) : list.append.assoc
private lemma perm_max_count_right {l r : list A} (h : l ~ r) : ∀ l₁ l₂, max_count l₁ l₂ l ~ max_count l₁ l₂ r :=
perm.induction_on h
(λ l₁ l₂, !perm.refl)
(λ x s₁ s₂ p ih l₁ l₂, by_cases
(suppose i : list.count x l₁ ≥ list.count x l₂,
begin unfold max_count, rewrite [*if_pos i], exact perm_app !perm.refl !ih end)
(suppose i : ¬ list.count x l₁ ≥ list.count x l₂,
begin unfold max_count, rewrite [*if_neg i], exact perm_app !perm.refl !ih end))
(λ x y l l₁ l₂, by_cases
(suppose i₁ : list.count x l₁ ≥ list.count x l₂, by_cases
(suppose i₂ : list.count y l₁ ≥ list.count y l₂,
begin unfold max_count, unfold max_count, rewrite [*if_pos i₁, *if_pos i₂], apply perm_app_left_comm end)
(suppose i₂ : ¬ list.count y l₁ ≥ list.count y l₂,
begin unfold max_count, unfold max_count, rewrite [*if_pos i₁, *if_neg i₂], apply perm_app_left_comm end))
(suppose i₁ : ¬ list.count x l₁ ≥ list.count x l₂, by_cases
(suppose i₂ : list.count y l₁ ≥ list.count y l₂,
begin unfold max_count, unfold max_count, rewrite [*if_neg i₁, *if_pos i₂], apply perm_app_left_comm end)
(suppose i₂ : ¬ list.count y l₁ ≥ list.count y l₂,
begin unfold max_count, unfold max_count, rewrite [*if_neg i₁, *if_neg i₂], apply perm_app_left_comm end)))
(λ s₁ s₂ s₃ p₁ p₂ ih₁ ih₂ l₁ l₂, perm.trans (ih₁ l₁ l₂) (ih₂ l₁ l₂))
private lemma perm_max_count {l₁ l₂ l₃ r₁ r₂ r₃ : list A} (p₁ : l₁ ~ r₁) (p₂ : l₂ ~ r₂) (p₃ : l₃ ~ r₃) : max_count l₁ l₂ l₃ ~ max_count r₁ r₂ r₃ :=
calc max_count l₁ l₂ l₃ ~ max_count r₁ r₂ l₃ : perm_max_count_left p₁ p₂
... ~ max_count r₁ r₂ r₃ : perm_max_count_right p₃
private lemma perm_min_count_left {l₁ l₂ l₃ l₄ : list A} (h₁ : l₁ ~ l₃) (h₂ : l₂ ~ l₄) : ∀ l, min_count l₁ l₂ l ~ min_count l₃ l₄ l
| [] := by esimp
| (a::l) :=
assert e₁ : list.count a l₁ = list.count a l₃, from count_eq_of_perm h₁ a,
assert e₂ : list.count a l₂ = list.count a l₄, from count_eq_of_perm h₂ a,
by_cases
(suppose list.count a l₁ ≤ list.count a l₂,
begin unfold min_count, rewrite [-e₁, -e₂, *if_pos this], exact perm_app !perm.refl !perm_min_count_left end)
(suppose ¬ list.count a l₁ ≤ list.count a l₂,
begin unfold min_count, rewrite [-e₁, -e₂, *if_neg this], exact perm_app !perm.refl !perm_min_count_left end)
private lemma perm_min_count_right {l r : list A} (h : l ~ r) : ∀ l₁ l₂, min_count l₁ l₂ l ~ min_count l₁ l₂ r :=
perm.induction_on h
(λ l₁ l₂, !perm.refl)
(λ x s₁ s₂ p ih l₁ l₂, by_cases
(suppose i : list.count x l₁ ≤ list.count x l₂,
begin unfold min_count, rewrite [*if_pos i], exact perm_app !perm.refl !ih end)
(suppose i : ¬ list.count x l₁ ≤ list.count x l₂,
begin unfold min_count, rewrite [*if_neg i], exact perm_app !perm.refl !ih end))
(λ x y l l₁ l₂, by_cases
(suppose i₁ : list.count x l₁ ≤ list.count x l₂, by_cases
(suppose i₂ : list.count y l₁ ≤ list.count y l₂,
begin unfold min_count, unfold min_count, rewrite [*if_pos i₁, *if_pos i₂], apply perm_app_left_comm end)
(suppose i₂ : ¬ list.count y l₁ ≤ list.count y l₂,
begin unfold min_count, unfold min_count, rewrite [*if_pos i₁, *if_neg i₂], apply perm_app_left_comm end))
(suppose i₁ : ¬ list.count x l₁ ≤ list.count x l₂, by_cases
(suppose i₂ : list.count y l₁ ≤ list.count y l₂,
begin unfold min_count, unfold min_count, rewrite [*if_neg i₁, *if_pos i₂], apply perm_app_left_comm end)
(suppose i₂ : ¬ list.count y l₁ ≤ list.count y l₂,
begin unfold min_count, unfold min_count, rewrite [*if_neg i₁, *if_neg i₂], apply perm_app_left_comm end)))
(λ s₁ s₂ s₃ p₁ p₂ ih₁ ih₂ l₁ l₂, perm.trans (ih₁ l₁ l₂) (ih₂ l₁ l₂))
private lemma perm_min_count {l₁ l₂ l₃ r₁ r₂ r₃ : list A} (p₁ : l₁ ~ r₁) (p₂ : l₂ ~ r₂) (p₃ : l₃ ~ r₃) : min_count l₁ l₂ l₃ ~ min_count r₁ r₂ r₃ :=
calc min_count l₁ l₂ l₃ ~ min_count r₁ r₂ l₃ : perm_min_count_left p₁ p₂
... ~ min_count r₁ r₂ r₃ : perm_min_count_right p₃
definition union (b₁ b₂ : bag A) : bag A :=
quot.lift_on₂ b₁ b₂ (λ l₁ l₂, ⟦max_count l₁ l₂ (union_list l₁ l₂)⟧)
(λ l₁ l₂ l₃ l₄ p₁ p₂, quot.sound (perm_max_count p₁ p₂ (perm_union_list p₁ p₂)))
infix := union
definition inter (b₁ b₂ : bag A) : bag A :=
quot.lift_on₂ b₁ b₂ (λ l₁ l₂, ⟦min_count l₁ l₂ (union_list l₁ l₂)⟧)
(λ l₁ l₂ l₃ l₄ p₁ p₂, quot.sound (perm_min_count p₁ p₂ (perm_union_list p₁ p₂)))
infix ∩ := inter
lemma count_union (a : A) (b₁ b₂ : bag A) : count a (b₁ b₂) = max (count a b₁) (count a b₂) :=
quot.induction_on₂ b₁ b₂ (λ l₁ l₂, by_cases
(suppose a ∈ union_list l₁ l₂, !max_count_eq this !nodup_union_list)
(suppose ¬ a ∈ union_list l₁ l₂,
assert ¬ a ∈ l₁, from not_mem_of_not_mem_union_list_left `¬ a ∈ union_list l₁ l₂`,
assert ¬ a ∈ l₂, from not_mem_of_not_mem_union_list_right `¬ a ∈ union_list l₁ l₂`,
assert n : ¬ a ∈ max_count l₁ l₂ (union_list l₁ l₂), from not_mem_max_count_of_not_mem l₁ l₂ `¬ a ∈ union_list l₁ l₂`,
begin
unfold [union, count],
rewrite [count_eq_zero_of_not_mem `¬ a ∈ l₁`, count_eq_zero_of_not_mem `¬ a ∈ l₂`, max_self],
rewrite [count_eq_zero_of_not_mem n]
end))
lemma count_inter (a : A) (b₁ b₂ : bag A) : count a (b₁ ∩ b₂) = min (count a b₁) (count a b₂) :=
quot.induction_on₂ b₁ b₂ (λ l₁ l₂, by_cases
(suppose a ∈ union_list l₁ l₂, !min_count_eq this !nodup_union_list)
(suppose ¬ a ∈ union_list l₁ l₂,
assert ¬ a ∈ l₁, from not_mem_of_not_mem_union_list_left `¬ a ∈ union_list l₁ l₂`,
assert ¬ a ∈ l₂, from not_mem_of_not_mem_union_list_right `¬ a ∈ union_list l₁ l₂`,
assert n : ¬ a ∈ min_count l₁ l₂ (union_list l₁ l₂), from not_mem_min_count_of_not_mem l₁ l₂ `¬ a ∈ union_list l₁ l₂`,
begin
unfold [inter, count],
rewrite [count_eq_zero_of_not_mem `¬ a ∈ l₁`, count_eq_zero_of_not_mem `¬ a ∈ l₂`, min_self],
rewrite [count_eq_zero_of_not_mem n]
end))
lemma union.comm (b₁ b₂ : bag A) : b₁ b₂ = b₂ b₁ :=
bag.ext (λ a, by rewrite [*count_union, max.comm])
lemma union.assoc (b₁ b₂ b₃ : bag A) : (b₁ b₂) b₃ = b₁ (b₂ b₃) :=
bag.ext (λ a, by rewrite [*count_union, max.assoc])
theorem union.left_comm (s₁ s₂ s₃ : bag A) : s₁ (s₂ s₃) = s₂ (s₁ s₃) :=
!left_comm union.comm union.assoc s₁ s₂ s₃
lemma union_self (b : bag A) : b b = b :=
bag.ext (λ a, by rewrite [*count_union, max_self])
lemma union_empty (b : bag A) : b empty = b :=
bag.ext (λ a, by rewrite [*count_union, count_empty, max_zero])
lemma empty_union (b : bag A) : empty b = b :=
calc empty b = b empty : union.comm
... = b : union_empty
lemma inter.comm (b₁ b₂ : bag A) : b₁ ∩ b₂ = b₂ ∩ b₁ :=
bag.ext (λ a, by rewrite [*count_inter, min.comm])
lemma inter.assoc (b₁ b₂ b₃ : bag A) : (b₁ ∩ b₂) ∩ b₃ = b₁ ∩ (b₂ ∩ b₃) :=
bag.ext (λ a, by rewrite [*count_inter, min.assoc])
theorem inter.left_comm (s₁ s₂ s₃ : bag A) : s₁ ∩ (s₂ ∩ s₃) = s₂ ∩ (s₁ ∩ s₃) :=
!left_comm inter.comm inter.assoc s₁ s₂ s₃
lemma inter_self (b : bag A) : b ∩ b = b :=
bag.ext (λ a, by rewrite [*count_inter, min_self])
lemma inter_empty (b : bag A) : b ∩ empty = empty :=
bag.ext (λ a, by rewrite [*count_inter, count_empty, min_zero])
lemma empty_inter (b : bag A) : empty ∩ b = empty :=
calc empty ∩ b = b ∩ empty : inter.comm
... = empty : inter_empty
lemma append_union_inter (b₁ b₂ : bag A) : (b₁ b₂) ++ (b₁ ∩ b₂) = b₁ ++ b₂ :=
bag.ext (λ a, begin
rewrite [*count_append, count_inter, count_union],
apply (or.elim (lt_or_ge (count a b₁) (count a b₂))),
{ intro H, rewrite [min_eq_left_of_lt H, max_eq_right_of_lt H, add.comm] },
{ intro H, rewrite [min_eq_right H, max_eq_left H, add.comm] }
end)
lemma inter.left_distrib (b₁ b₂ b₃ : bag A) : b₁ ∩ (b₂ b₃) = (b₁ ∩ b₂) (b₁ ∩ b₃) :=
bag.ext (λ a, begin
rewrite [*count_inter, *count_union, *count_inter],
apply (@by_cases (count a b₁ ≤ count a b₂)),
{ intro H₁₂, apply (@by_cases (count a b₂ ≤ count a b₃)),
{ intro H₂₃,
have H₁₃ : count a b₁ ≤ count a b₃, from le.trans H₁₂ H₂₃,
rewrite [max_eq_right H₂₃, min_eq_left H₁₂, min_eq_left H₁₃, max_self]},
{ intro H₂₃,
rewrite [min_eq_left H₁₂, max.comm, max_eq_right_of_lt (lt_of_not_ge H₂₃) ],
apply (@by_cases (count a b₁ ≤ count a b₃)),
{ intro H₁₃, rewrite [min_eq_left H₁₃, max_self, min_eq_left H₁₂] },
{ intro H₁₃,
rewrite [min.comm (count a b₁) (count a b₃), min_eq_left_of_lt (lt_of_not_ge H₁₃),
min_eq_left H₁₂, max.comm, max_eq_right_of_lt (lt_of_not_ge H₁₃)]}}},
{ intro H₁₂, apply (@by_cases (count a b₂ ≤ count a b₃)),
{ intro H₂₃,
rewrite [max_eq_right H₂₃],
apply (@by_cases (count a b₁ ≤ count a b₃)),
{ intro H₁₃, rewrite [min_eq_left H₁₃, min.comm, min_eq_left_of_lt (lt_of_not_ge H₁₂), max_eq_right_of_lt (lt_of_not_ge H₁₂)] },
{ intro H₁₃, rewrite [min.comm, min_eq_left_of_lt (lt_of_not_ge H₁₃), min.comm, min_eq_left_of_lt (lt_of_not_ge H₁₂), max_eq_right H₂₃] } },
{ intro H₂₃,
have H₁₃ : count a b₁ > count a b₃, from lt.trans (lt_of_not_ge H₂₃) (lt_of_not_ge H₁₂),
rewrite [max.comm, max_eq_right_of_lt (lt_of_not_ge H₂₃), min.comm, min_eq_left_of_lt (lt_of_not_ge H₁₂)],
rewrite [min.comm, min_eq_left_of_lt H₁₃, max.comm, max_eq_right_of_lt (lt_of_not_ge H₂₃)] } }
end)
lemma inter.right_distrib (b₁ b₂ b₃ : bag A) : (b₁ b₂) ∩ b₃ = (b₁ ∩ b₃) (b₂ ∩ b₃) :=
calc (b₁ b₂) ∩ b₃ = b₃ ∩ (b₁ b₂) : inter.comm
... = (b₃ ∩ b₁) (b₃ ∩ b₂) : inter.left_distrib
... = (b₁ ∩ b₃) (b₃ ∩ b₂) : inter.comm
... = (b₁ ∩ b₃) (b₂ ∩ b₃) : inter.comm
end union_inter
section subbag
variable [decA : decidable_eq A]
include decA
definition subbag (b₁ b₂ : bag A) := ∀ a, count a b₁ ≤ count a b₂
infix ⊆ := subbag
lemma subbag.refl (b : bag A) : b ⊆ b :=
take a, !le.refl
lemma subbag.trans {b₁ b₂ b₃ : bag A} : b₁ ⊆ b₂ → b₂ ⊆ b₃ → b₁ ⊆ b₃ :=
assume h₁ h₂, take a, le.trans (h₁ a) (h₂ a)
lemma subbag.antisymm {b₁ b₂ : bag A} : b₁ ⊆ b₂ → b₂ ⊆ b₁ → b₁ = b₂ :=
assume h₁ h₂, bag.ext (take a, le.antisymm (h₁ a) (h₂ a))
lemma count_le_of_subbag {b₁ b₂ : bag A} : b₁ ⊆ b₂ → ∀ a, count a b₁ ≤ count a b₂ :=
assume h, h
lemma subbag.intro {b₁ b₂ : bag A} : (∀ a, count a b₁ ≤ count a b₂) → b₁ ⊆ b₂ :=
assume h, h
lemma empty_subbag (b : bag A) : empty ⊆ b :=
subbag.intro (take a, !zero_le)
lemma eq_empty_of_subbag_empty {b : bag A} : b ⊆ empty → b = empty :=
assume h, subbag.antisymm h (empty_subbag b)
lemma union_subbag_of_subbag_of_subbag {b₁ b₂ b₃ : bag A} : b₁ ⊆ b₃ → b₂ ⊆ b₃ → b₁ b₂ ⊆ b₃ :=
assume h₁ h₂, subbag.intro (λ a, calc
count a (b₁ b₂) = max (count a b₁) (count a b₂) : by rewrite count_union
... ≤ count a b₃ : max_le (h₁ a) (h₂ a))
lemma subbag_inter_of_subbag_of_subbag {b₁ b₂ b₃ : bag A} : b₁ ⊆ b₂ → b₁ ⊆ b₃ → b₁ ⊆ b₂ ∩ b₃ :=
assume h₁ h₂, subbag.intro (λ a, calc
count a b₁ ≤ min (count a b₂) (count a b₃) : le_min (h₁ a) (h₂ a)
... = count a (b₂ ∩ b₃) : by rewrite count_inter)
lemma subbag_union_left (b₁ b₂ : bag A) : b₁ ⊆ b₁ b₂ :=
subbag.intro (take a, by rewrite [count_union]; apply le_max_left)
lemma subbag_union_right (b₁ b₂ : bag A) : b₂ ⊆ b₁ b₂ :=
subbag.intro (take a, by rewrite [count_union]; apply le_max_right)
lemma inter_subbag_left (b₁ b₂ : bag A) : b₁ ∩ b₂ ⊆ b₁ :=
subbag.intro (take a, by rewrite [count_inter]; apply min_le_left)
lemma inter_subbag_right (b₁ b₂ : bag A) : b₁ ∩ b₂ ⊆ b₂ :=
subbag.intro (take a, by rewrite [count_inter]; apply min_le_right)
lemma subbag_append_left (b₁ b₂ : bag A) : b₁ ⊆ b₁ ++ b₂ :=
subbag.intro (take a, by rewrite [count_append]; apply le_add_right)
lemma subbag_append_right (b₁ b₂ : bag A) : b₂ ⊆ b₁ ++ b₂ :=
subbag.intro (take a, by rewrite [count_append]; apply le_add_left)
lemma inter_subbag_union (b₁ b₂ : bag A) : b₁ ∩ b₂ ⊆ b₁ b₂ :=
subbag.trans (inter_subbag_left b₁ b₂) (subbag_union_left b₁ b₂)
open decidable
lemma union_subbag_append (b₁ b₂ : bag A) : b₁ b₂ ⊆ b₁ ++ b₂ :=
subbag.intro (take a, begin
rewrite [count_append, count_union],
exact (or.elim !lt_or_ge)
(suppose count a b₁ < count a b₂, by rewrite [max_eq_right_of_lt this]; apply le_add_left)
(suppose count a b₁ ≥ count a b₂, by rewrite [max_eq_left this]; apply le_add_right)
end)
lemma subbag_insert (a : A) (b : bag A) : b ⊆ insert a b :=
subbag.intro (take x, by_cases
(suppose x = a, by rewrite [this, count_insert]; apply le_succ)
(suppose x ≠ a, by rewrite [count_insert_of_ne this]))
lemma mem_of_subbag_of_mem {a : A} {b₁ b₂ : bag A} : b₁ ⊆ b₂ → a ∈ b₁ → a ∈ b₂ :=
assume h₁ h₂,
have count a b₁ ≤ count a b₂, from count_le_of_subbag h₁ a,
have count a b₁ > 0, from h₂,
show count a b₂ > 0, from lt_of_lt_of_le `0 < count a b₁` `count a b₁ ≤ count a b₂`
lemma extract_subbag (a : A) (b : bag A) : extract a b ⊆ b :=
subbag.intro (take x, by_cases
(suppose x = a, by rewrite [this, count_extract]; apply zero_le)
(suppose x ≠ a, by rewrite [count_extract_of_ne this]))
open bool
private definition subcount : list A → list A → bool
| [] l₂ := tt
| (a::l₁) l₂ := if list.count a (a::l₁) ≤ list.count a l₂ then subcount l₁ l₂ else ff
private lemma all_of_subcount_eq_tt : ∀ {l₁ l₂ : list A}, subcount l₁ l₂ = tt → ∀ a, list.count a l₁ ≤ list.count a l₂
| [] l₂ h := take x, !zero_le
| (a::l₁) l₂ h := take x,
have subcount l₁ l₂ = tt, from by_contradiction (suppose subcount l₁ l₂ ≠ tt,
assert subcount l₁ l₂ = ff, from eq_ff_of_ne_tt this,
begin unfold subcount at h, rewrite [this at h, if_t_t at h], contradiction end),
assert ih : ∀ a, list.count a l₁ ≤ list.count a l₂, from all_of_subcount_eq_tt this,
assert i : list.count a (a::l₁) ≤ list.count a l₂, from by_contradiction (suppose ¬ list.count a (a::l₁) ≤ list.count a l₂,
begin unfold subcount at h, rewrite [if_neg this at h], contradiction end),
by_cases
(suppose x = a, by rewrite this; apply i)
(suppose x ≠ a, by rewrite [list.count_cons_of_ne this]; apply ih)
private lemma ex_of_subcount_eq_ff : ∀ {l₁ l₂ : list A}, subcount l₁ l₂ = ff → ∃ a, ¬ list.count a l₁ ≤ list.count a l₂
| [] l₂ h := by contradiction
| (a::l₁) l₂ h := by_cases
(suppose i : list.count a (a::l₁) ≤ list.count a l₂,
have subcount l₁ l₂ = ff, from by_contradiction (suppose subcount l₁ l₂ ≠ ff,
assert subcount l₁ l₂ = tt, from eq_tt_of_ne_ff this,
begin
unfold subcount at h,
rewrite [if_pos i at h, this at h],
contradiction
end),
have ih : ∃ a, ¬ list.count a l₁ ≤ list.count a l₂, from ex_of_subcount_eq_ff this,
obtain w hw, from ih, by_cases
(suppose w = a, begin subst w, existsi a, rewrite list.count_cons_eq, apply not_lt_of_ge, apply le_of_lt (lt_of_not_ge hw) end)
(suppose w ≠ a, exists.intro w (by rewrite (list.count_cons_of_ne `w ≠ a`); exact hw)))
(suppose ¬ list.count a (a::l₁) ≤ list.count a l₂, exists.intro a this)
definition decidable_subbag [instance] (b₁ b₂ : bag A) : decidable (b₁ ⊆ b₂) :=
quot.rec_on_subsingleton₂ b₁ b₂ (λ l₁ l₂,
match subcount l₁ l₂ with
| tt := suppose subcount l₁ l₂ = tt, inl (all_of_subcount_eq_tt this)
| ff := suppose subcount l₁ l₂ = ff, inr (suppose h : (∀ a, list.count a l₁ ≤ list.count a l₂),
obtain w hw, from ex_of_subcount_eq_ff `subcount l₁ l₂ = ff`,
absurd (h w) hw)
end rfl)
end subbag
end bag