lean2/library/init/quot.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
Quotient types.
-/
prelude
import init.sigma init.setoid init.logic
open sigma.ops setoid
constant quot.{l} : Π {A : Type.{l}}, setoid A → Type.{l}
-- Remark: if we do not use propext here, then we would need a quot.lift for propositions.
constant propext {a b : Prop} : (a ↔ b) → a = b
-- iff can now be used to do substitutions in a calculation
theorem iff_subst [subst] {a b : Prop} {P : Prop → Prop} (H₁ : a ↔ b) (H₂ : P a) : P b :=
eq.subst (propext H₁) H₂
namespace quot
protected constant mk : Π {A : Type} [s : setoid A], A → quot s
notation `⟦`:max a `⟧`:0 := quot.mk a
constant sound : Π {A : Type} [s : setoid A] {a b : A}, a ≈ b → ⟦a⟧ = ⟦b⟧
constant lift : Π {A B : Type} [s : setoid A] (f : A → B), (∀ a b, a ≈ b → f a = f b) → quot s → B
constant ind : ∀ {A : Type} [s : setoid A] {B : quot s → Prop}, (∀ a, B ⟦a⟧) → ∀ q, B q
init_quotient
protected theorem lift_beta {A B : Type} [setoid A] (f : A → B) (c : ∀ a b, a ≈ b → f a = f b) (a : A) : lift f c ⟦a⟧ = f a :=
rfl
protected theorem ind_beta {A : Type} [s : setoid A] {B : quot s → Prop} (p : ∀ a, B ⟦a⟧) (a : A) : ind p ⟦a⟧ = p a :=
rfl
protected definition lift_on [reducible] {A B : Type} [s : setoid A] (q : quot s) (f : A → B) (c : ∀ a b, a ≈ b → f a = f b) : B :=
lift f c q
protected theorem induction_on {A : Type} [s : setoid A] {B : quot s → Prop} (q : quot s) (H : ∀ a, B ⟦a⟧) : B q :=
ind H q
theorem exists_rep {A : Type} [s : setoid A] (q : quot s) : ∃ a : A, ⟦a⟧ = q :=
quot.induction_on q (λ a, exists.intro a rfl)
section
variable {A : Type}
variable [s : setoid A]
variable {B : quot s → Type}
include s
protected definition indep [reducible] (f : Π a, B ⟦a⟧) (a : A) : Σ q, B q :=
⟨⟦a⟧, f a⟩
protected lemma indep_coherent (f : Π a, B ⟦a⟧)
(H : ∀ (a b : A) (p : a ≈ b), eq.rec (f a) (sound p) = f b)
: ∀ a b, a ≈ b → quot.indep f a = quot.indep f b :=
λa b e, sigma.eq (sound e) (H a b e)
protected lemma lift_indep_pr1
(f : Π a, B ⟦a⟧) (H : ∀ (a b : A) (p : a ≈ b), eq.rec (f a) (sound p) = f b)
(q : quot s) : (lift (quot.indep f) (quot.indep_coherent f H) q).1 = q :=
quot.ind (λ a, by esimp) q
protected definition rec [reducible]
(f : Π a, B ⟦a⟧) (H : ∀ (a b : A) (p : a ≈ b), eq.rec (f a) (sound p) = f b)
(q : quot s) : B q :=
let p := lift (quot.indep f) (quot.indep_coherent f H) q in
eq.rec_on (quot.lift_indep_pr1 f H q) (p.2)
protected definition rec_on [reducible]
(q : quot s) (f : Π a, B ⟦a⟧) (H : ∀ (a b : A) (p : a ≈ b), eq.rec (f a) (sound p) = f b) : B q :=
quot.rec f H q
protected definition rec_on_subsingleton [reducible]
[H : ∀ a, subsingleton (B ⟦a⟧)] (q : quot s) (f : Π a, B ⟦a⟧) : B q :=
quot.rec f (λ a b h, !subsingleton.elim) q
protected definition hrec_on [reducible]
(q : quot s) (f : Π a, B ⟦a⟧) (c : ∀ (a b : A) (p : a ≈ b), f a == f b) : B q :=
quot.rec_on q f
(λ a b p, eq_of_heq (calc
eq.rec (f a) (sound p) == f a : eq_rec_heq
... == f b : c a b p))
end
section
variables {A B C : Type}
variables [s₁ : setoid A] [s₂ : setoid B]
include s₁ s₂
protected definition lift₂ [reducible]
(f : A → B → C)(c : ∀ a₁ a₂ b₁ b₂, a₁ ≈ b₁ → a₂ ≈ b₂ → f a₁ a₂ = f b₁ b₂)
(q₁ : quot s₁) (q₂ : quot s₂) : C :=
quot.lift
(λ a₁, lift (λ a₂, f a₁ a₂) (λ a b H, c a₁ a a₁ b (setoid.refl a₁) H) q₂)
(λ a b H, ind (λ a', proof c a a' b a' H (setoid.refl a') qed) q₂)
q₁
protected definition lift_on₂ [reducible]
(q₁ : quot s₁) (q₂ : quot s₂) (f : A → B → C) (c : ∀ a₁ a₂ b₁ b₂, a₁ ≈ b₁ → a₂ ≈ b₂ → f a₁ a₂ = f b₁ b₂) : C :=
quot.lift₂ f c q₁ q₂
protected theorem ind₂ {C : quot s₁ → quot s₂ → Prop} (H : ∀ a b, C ⟦a⟧ ⟦b⟧) (q₁ : quot s₁) (q₂ : quot s₂) : C q₁ q₂ :=
quot.ind (λ a₁, quot.ind (λ a₂, H a₁ a₂) q₂) q₁
protected theorem induction_on₂
{C : quot s₁ → quot s₂ → Prop} (q₁ : quot s₁) (q₂ : quot s₂) (H : ∀ a b, C ⟦a⟧ ⟦b⟧) : C q₁ q₂ :=
quot.ind (λ a₁, quot.ind (λ a₂, H a₁ a₂) q₂) q₁
protected theorem induction_on₃
[s₃ : setoid C]
{D : quot s₁ → quot s₂ → quot s₃ → Prop} (q₁ : quot s₁) (q₂ : quot s₂) (q₃ : quot s₃) (H : ∀ a b c, D ⟦a⟧ ⟦b⟧ ⟦c⟧)
: D q₁ q₂ q₃ :=
quot.ind (λ a₁, quot.ind (λ a₂, quot.ind (λ a₃, H a₁ a₂ a₃) q₃) q₂) q₁
end
section exact
variable {A : Type}
variable [s : setoid A]
include s
private definition rel (q₁ q₂ : quot s) : Prop :=
quot.lift_on₂ q₁ q₂
(λ a₁ a₂, a₁ ≈ a₂)
(λ a₁ a₂ b₁ b₂ a₁b₁ a₂b₂,
propext (iff.intro
(λ a₁a₂, setoid.trans (setoid.symm a₁b₁) (setoid.trans a₁a₂ a₂b₂))
(λ b₁b₂, setoid.trans a₁b₁ (setoid.trans b₁b₂ (setoid.symm a₂b₂)))))
local infix `~` := rel
private lemma rel.refl : ∀ q : quot s, q ~ q :=
λ q, quot.induction_on q (λ a, setoid.refl a)
private lemma eq_imp_rel {q₁ q₂ : quot s} : q₁ = q₂ → q₁ ~ q₂ :=
assume h, eq.rec_on h (rel.refl q₁)
theorem exact {a b : A} : ⟦a⟧ = ⟦b⟧ → a ≈ b :=
assume h, eq_imp_rel h
end exact
section
variables {A B : Type}
variables [s₁ : setoid A] [s₂ : setoid B]
include s₁ s₂
variable {C : quot s₁ → quot s₂ → Type}
protected definition rec_on_subsingleton₂ [reducible]
{C : quot s₁ → quot s₂ → Type₁} [H : ∀ a b, subsingleton (C ⟦a⟧ ⟦b⟧)]
(q₁ : quot s₁) (q₂ : quot s₂) (f : Π a b, C ⟦a⟧ ⟦b⟧) : C q₁ q₂:=
@quot.rec_on_subsingleton _ _ _
(λ a, quot.ind _ _)
q₁ (λ a, quot.rec_on_subsingleton q₂ (λ b, f a b))
protected definition hrec_on₂ [reducible]
{C : quot s₁ → quot s₂ → Type₁} (q₁ : quot s₁) (q₂ : quot s₂)
(f : Π a b, C ⟦a⟧ ⟦b⟧) (c : ∀ a₁ a₂ b₁ b₂, a₁ ≈ b₁ → a₂ ≈ b₂ → f a₁ a₂ == f b₁ b₂) : C q₁ q₂:=
quot.hrec_on q₁
(λ a, quot.hrec_on q₂ (λ b, f a b) (λ b₁ b₂ p, c _ _ _ _ !setoid.refl p))
(λ a₁ a₂ p, quot.induction_on q₂
(λ b,
have aux : f a₁ b == f a₂ b, from c _ _ _ _ p !setoid.refl,
calc quot.hrec_on ⟦b⟧ (λ (b : B), f a₁ b) _
== f a₁ b : eq_rec_heq
... == f a₂ b : aux
... == quot.hrec_on ⟦b⟧ (λ (b : B), f a₂ b) _ : eq_rec_heq))
end
end quot
attribute quot.mk [constructor]
attribute quot.lift_on [unfold 4]
attribute quot.rec [unfold 6]
attribute quot.rec_on [unfold 4]
attribute quot.hrec_on [unfold 4]
attribute quot.rec_on_subsingleton [unfold 5]
attribute quot.lift₂ [unfold 8]
attribute quot.lift_on₂ [unfold 6]
attribute quot.hrec_on₂ [unfold 6]
attribute quot.rec_on_subsingleton₂ [unfold 7]
open decidable
definition quot.has_decidable_eq [instance] {A : Type} {s : setoid A} [decR : ∀ a b : A, decidable (a ≈ b)] : decidable_eq (quot s) :=
λ q₁ q₂ : quot s,
quot.rec_on_subsingleton₂ q₁ q₂
(λ a₁ a₂,
match decR a₁ a₂ with
| inl h₁ := inl (quot.sound h₁)
| inr h₂ := inr (λ h, absurd (quot.exact h) h₂)
end)