lean2/library/init/logic.lean

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/-
Copyright (c) 2014 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura, Jeremy Avigad, Floris van Doorn
-/
prelude
import init.datatypes init.reserved_notation
/- implication -/
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definition implies (a b : Prop) := a → b
lemma implies.trans [trans] {p q r : Prop} (h₁ : implies p q) (h₂ : implies q r) : implies p r :=
assume hp, h₂ (h₁ hp)
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definition trivial := true.intro
definition not (a : Prop) := a → false
prefix `¬` := not
definition absurd {a : Prop} {b : Type} (H1 : a) (H2 : ¬a) : b :=
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false.rec b (H2 H1)
theorem mt {a b : Prop} (H1 : a → b) (H2 : ¬b) : ¬a :=
assume Ha : a, absurd (H1 Ha) H2
/- not -/
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theorem not_false : ¬false :=
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assume H : false, H
definition non_contradictory (a : Prop) : Prop := ¬¬a
theorem non_contradictory_intro {a : Prop} (Ha : a) : ¬¬a :=
assume Hna : ¬a, absurd Ha Hna
/- false -/
theorem false.elim {c : Prop} (H : false) : c :=
false.rec c H
/- eq -/
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notation a = b := eq a b
definition rfl {A : Type} {a : A} : a = a := eq.refl a
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-- proof irrelevance is built in
theorem proof_irrel {a : Prop} (H₁ H₂ : a) : H₁ = H₂ :=
rfl
-- Remark: we provide the universe levels explicitly to make sure `eq.drec` has the same type of `eq.rec` in the HoTT library
protected theorem eq.drec.{l₁ l₂} {A : Type.{l₂}} {a : A} {C : Π (x : A), a = x → Type.{l₁}} (h₁ : C a (eq.refl a)) {b : A} (h₂ : a = b) : C b h₂ :=
eq.rec (λh₂ : a = a, show C a h₂, from h₁) h₂ h₂
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namespace eq
variables {A : Type}
variables {a b c a': A}
protected theorem drec_on {a : A} {C : Π (x : A), a = x → Type} {b : A} (h₂ : a = b) (h₁ : C a (refl a)) : C b h₂ :=
eq.drec h₁ h₂
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theorem subst {P : A → Prop} (H₁ : a = b) (H₂ : P a) : P b :=
eq.rec H₂ H₁
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theorem trans (H₁ : a = b) (H₂ : b = c) : a = c :=
subst H₂ H₁
theorem symm : a = b → b = a :=
eq.rec (refl a)
theorem substr {P : A → Prop} (H₁ : b = a) : P a → P b :=
subst (symm H₁)
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theorem mp {a b : Type} : (a = b) → a → b :=
eq.rec_on
theorem mpr {a b : Type} : (a = b) → b → a :=
assume H₁ H₂, eq.rec_on (eq.symm H₁) H₂
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namespace ops
notation H `⁻¹` := symm H --input with \sy or \-1 or \inv
notation H1 ⬝ H2 := trans H1 H2
notation H1 ▸ H2 := subst H1 H2
notation H1 ▹ H2 := eq.rec H2 H1
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end ops
end eq
theorem congr {A B : Type} {f₁ f₂ : A → B} {a₁ a₂ : A} (H₁ : f₁ = f₂) (H₂ : a₁ = a₂) : f₁ a₁ = f₂ a₂ :=
eq.subst H₁ (eq.subst H₂ rfl)
theorem congr_fun {A : Type} {B : A → Type} {f g : Π x, B x} (H : f = g) (a : A) : f a = g a :=
eq.subst H (eq.refl (f a))
theorem congr_arg {A B : Type} {a₁ a₂ : A} (f : A → B) : a₁ = a₂ → f a₁ = f a₂ :=
congr rfl
section
variables {A : Type} {a b c: A}
open eq.ops
theorem trans_rel_left (R : A → A → Prop) (H₁ : R a b) (H₂ : b = c) : R a c :=
H₂ ▸ H₁
theorem trans_rel_right (R : A → A → Prop) (H₁ : a = b) (H₂ : R b c) : R a c :=
H₁⁻¹ ▸ H₂
end
section
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variable {p : Prop}
open eq.ops
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theorem of_eq_true (H : p = true) : p :=
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H⁻¹ ▸ trivial
theorem not_of_eq_false (H : p = false) : ¬p :=
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assume Hp, H ▸ Hp
end
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attribute eq.subst [subst]
attribute eq.refl [refl]
attribute eq.trans [trans]
attribute eq.symm [symm]
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/- ne -/
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definition ne [reducible] {A : Type} (a b : A) := ¬(a = b)
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notation a ≠ b := ne a b
namespace ne
open eq.ops
variable {A : Type}
variables {a b : A}
theorem intro (H : a = b → false) : a ≠ b := H
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theorem elim (H : a ≠ b) : a = b → false := H
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theorem irrefl (H : a ≠ a) : false := H rfl
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theorem symm (H : a ≠ b) : b ≠ a :=
assume (H₁ : b = a), H (H₁⁻¹)
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end ne
theorem false_of_ne {A : Type} {a : A} : a ≠ a → false := ne.irrefl
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section
open eq.ops
variables {p : Prop}
theorem ne_false_of_self : p → p ≠ false :=
assume (Hp : p) (Heq : p = false), Heq ▸ Hp
theorem ne_true_of_not : ¬p → p ≠ true :=
assume (Hnp : ¬p) (Heq : p = true), (Heq ▸ Hnp) trivial
theorem true_ne_false : ¬true = false :=
ne_false_of_self trivial
end
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infixl ` == `:50 := heq
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namespace heq
universe variable u
variables {A B C : Type.{u}} {a a' : A} {b b' : B} {c : C}
theorem to_eq (H : a == a') : a = a' :=
have H₁ : ∀ (Ht : A = A), eq.rec a Ht = a, from
λ Ht, eq.refl a,
heq.rec H₁ H (eq.refl A)
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theorem elim {A : Type} {a : A} {P : A → Type} {b : A} (H₁ : a == b)
: P a → P b := eq.rec_on (to_eq H₁)
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theorem subst {P : ∀T : Type, T → Prop} : a == b → P A a → P B b :=
heq.rec_on
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theorem symm (H : a == b) : b == a :=
heq.rec_on H (refl a)
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theorem of_eq (H : a = a') : a == a' :=
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eq.subst H (refl a)
theorem trans (H₁ : a == b) (H₂ : b == c) : a == c :=
subst H₂ H₁
theorem of_heq_of_eq (H₁ : a == b) (H₂ : b = b') : a == b' :=
trans H₁ (of_eq H₂)
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theorem of_eq_of_heq (H₁ : a = a') (H₂ : a' == b) : a == b :=
trans (of_eq H₁) H₂
definition type_eq (H : a == b) : A = B :=
heq.rec_on H (eq.refl A)
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end heq
open eq.ops
theorem eq_rec_heq {A : Type} {P : A → Type} {a a' : A} (H : a = a') (p : P a) : H ▹ p == p :=
eq.drec_on H !heq.refl
theorem heq_of_eq_rec_left {A : Type} {P : A → Type} : ∀ {a a' : A} {p₁ : P a} {p₂ : P a'} (e : a = a') (h₂ : e ▹ p₁ = p₂), p₁ == p₂
| a a p₁ p₂ (eq.refl a) h := eq.rec_on h !heq.refl
theorem heq_of_eq_rec_right {A : Type} {P : A → Type} : ∀ {a a' : A} {p₁ : P a} {p₂ : P a'} (e : a' = a) (h₂ : p₁ = e ▹ p₂), p₁ == p₂
| a a p₁ p₂ (eq.refl a) h := eq.rec_on h !heq.refl
theorem of_heq_true {a : Prop} (H : a == true) : a :=
of_eq_true (heq.to_eq H)
theorem eq_rec_compose : ∀ {A B C : Type} (p₁ : B = C) (p₂ : A = B) (a : A), p₁ ▹ (p₂ ▹ a : B) = (p₂ ⬝ p₁) ▹ a
| A A A (eq.refl A) (eq.refl A) a := calc
eq.refl A ▹ eq.refl A ▹ a = eq.refl A ▹ a : rfl
... = (eq.refl A ⬝ eq.refl A) ▹ a : {proof_irrel (eq.refl A) (eq.refl A ⬝ eq.refl A)}
theorem eq_rec_eq_eq_rec {A₁ A₂ : Type} {p : A₁ = A₂} : ∀ {a₁ : A₁} {a₂ : A₂}, p ▹ a₁ = a₂ → a₁ = p⁻¹ ▹ a₂ :=
eq.drec_on p (λ a₁ a₂ h, eq.drec_on h rfl)
theorem eq_rec_of_heq_left : ∀ {A₁ A₂ : Type} {a₁ : A₁} {a₂ : A₂} (h : a₁ == a₂), heq.type_eq h ▹ a₁ = a₂
| A A a a (heq.refl a) := rfl
theorem eq_rec_of_heq_right {A₁ A₂ : Type} {a₁ : A₁} {a₂ : A₂} (h : a₁ == a₂) : a₁ = (heq.type_eq h)⁻¹ ▹ a₂ :=
eq_rec_eq_eq_rec (eq_rec_of_heq_left h)
attribute heq.refl [refl]
attribute heq.trans [trans]
attribute heq.of_heq_of_eq [trans]
attribute heq.of_eq_of_heq [trans]
attribute heq.symm [symm]
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/- and -/
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notation a /\ b := and a b
notation a ∧ b := and a b
variables {a b c d : Prop}
theorem and.elim (H₁ : a ∧ b) (H₂ : a → b → c) : c :=
and.rec H₂ H₁
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/- or -/
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notation a \/ b := or a b
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notation a b := or a b
namespace or
theorem elim (H₁ : a b) (H₂ : a → c) (H₃ : b → c) : c :=
or.rec H₂ H₃ H₁
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end or
theorem non_contradictory_em (a : Prop) : ¬¬(a ¬a) :=
assume not_em : ¬(a ¬a),
have neg_a : ¬a, from
assume pos_a : a, absurd (or.inl pos_a) not_em,
absurd (or.inr neg_a) not_em
/- iff -/
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definition iff (a b : Prop) := (a → b) ∧ (b → a)
notation a <-> b := iff a b
notation a ↔ b := iff a b
namespace iff
theorem intro : (a → b) → (b → a) → (a ↔ b) := and.intro
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theorem elim : ((a → b) → (b → a) → c) → (a ↔ b) → c := and.rec
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theorem elim_left : (a ↔ b) → a → b := and.left
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definition mp := @elim_left
theorem elim_right : (a ↔ b) → b → a := and.right
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definition mpr := @elim_right
theorem refl (a : Prop) : a ↔ a :=
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intro (assume H, H) (assume H, H)
theorem rfl {a : Prop} : a ↔ a :=
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refl a
theorem trans (H₁ : a ↔ b) (H₂ : b ↔ c) : a ↔ c :=
intro
(assume Ha, mp H₂ (mp H₁ Ha))
(assume Hc, mpr H₁ (mpr H₂ Hc))
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theorem symm (H : a ↔ b) : b ↔ a :=
intro (elim_right H) (elim_left H)
theorem comm : (a ↔ b) ↔ (b ↔ a) :=
intro symm symm
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open eq.ops
theorem of_eq {a b : Prop} (H : a = b) : a ↔ b :=
H ▸ rfl
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end iff
theorem not_iff_not_of_iff (H₁ : a ↔ b) : ¬a ↔ ¬b :=
iff.intro
(assume (Hna : ¬ a) (Hb : b), Hna (iff.elim_right H₁ Hb))
(assume (Hnb : ¬ b) (Ha : a), Hnb (iff.elim_left H₁ Ha))
theorem of_iff_true (H : a ↔ true) : a :=
iff.mp (iff.symm H) trivial
theorem not_of_iff_false : (a ↔ false) → ¬a := iff.mp
theorem iff_true_intro (H : a) : a ↔ true :=
iff.intro
(λ Hl, trivial)
(λ Hr, H)
theorem iff_false_intro (H : ¬a) : a ↔ false :=
iff.intro H !false.rec
theorem not_non_contradictory_iff_absurd (a : Prop) : ¬¬¬a ↔ ¬a :=
iff.intro
(λ (Hl : ¬¬¬a) (Ha : a), Hl (non_contradictory_intro Ha))
absurd
attribute iff.refl [refl]
attribute iff.symm [symm]
attribute iff.trans [trans]
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theorem not_not_intro (Ha : a) : ¬¬a :=
assume Hna : ¬a, Hna Ha
theorem not_true : (¬ true) ↔ false :=
iff_false_intro (not_not_intro trivial)
theorem not_false_iff : (¬ false) ↔ true :=
iff_true_intro not_false
theorem ne_self_iff_false {A : Type} (a : A) : (a ≠ a) ↔ false :=
iff.intro false_of_ne false.elim
theorem eq_self_iff_true {A : Type} (a : A) : (a = a) ↔ true :=
iff_true_intro rfl
theorem heq_self_iff_true {A : Type} (a : A) : (a == a) ↔ true :=
iff_true_intro (heq.refl a)
theorem iff_not_self (a : Prop) : (a ↔ ¬a) ↔ false :=
iff_false_intro (λ H,
have H' : ¬a, from (λ Ha, (iff.mp H Ha) Ha),
H' (iff.mpr H H'))
theorem true_iff_false : (true ↔ false) ↔ false :=
iff_false_intro (λ H, iff.mp H trivial)
theorem false_iff_true : (false ↔ true) ↔ false :=
iff_false_intro (λ H, iff.mpr H trivial)
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inductive Exists {A : Type} (P : A → Prop) : Prop :=
intro : ∀ (a : A), P a → Exists P
definition exists.intro := @Exists.intro
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notation `exists` binders `, ` r:(scoped P, Exists P) := r
notation `∃` binders `, ` r:(scoped P, Exists P) := r
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theorem exists.elim {A : Type} {p : A → Prop} {B : Prop}
(H1 : ∃x, p x) (H2 : ∀ (a : A), p a → B) : B :=
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Exists.rec H2 H1
/- decidable -/
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inductive decidable [class] (p : Prop) : Type :=
| inl : p → decidable p
| inr : ¬p → decidable p
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definition decidable_true [instance] : decidable true :=
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decidable.inl trivial
definition decidable_false [instance] : decidable false :=
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decidable.inr not_false
-- We use "dependent" if-then-else to be able to communicate the if-then-else condition
-- to the branches
definition dite (c : Prop) [H : decidable c] {A : Type} : (c → A) → (¬ c → A) → A :=
decidable.rec_on H
/- if-then-else -/
definition ite (c : Prop) [H : decidable c] {A : Type} (t e : A) : A :=
decidable.rec_on H (λ Hc, t) (λ Hnc, e)
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namespace decidable
variables {p q : Prop}
definition rec_on_true [H : decidable p] {H1 : p → Type} {H2 : ¬p → Type} (H3 : p) (H4 : H1 H3)
: decidable.rec_on H H1 H2 :=
decidable.rec_on H (λh, H4) (λh, !false.rec (h H3))
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definition rec_on_false [H : decidable p] {H1 : p → Type} {H2 : ¬p → Type} (H3 : ¬p) (H4 : H2 H3)
: decidable.rec_on H H1 H2 :=
decidable.rec_on H (λh, false.rec _ (H3 h)) (λh, H4)
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definition by_cases {q : Type} [C : decidable p] : (p → q) → (¬p → q) → q := !dite
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theorem em (p : Prop) [H : decidable p] : p ¬p := by_cases or.inl or.inr
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theorem by_contradiction [Hp : decidable p] (H : ¬p → false) : p :=
if H1 : p then H1 else false.rec _ (H H1)
end decidable
section
variables {p q : Prop}
open decidable
definition decidable_of_decidable_of_iff (Hp : decidable p) (H : p ↔ q) : decidable q :=
if Hp : p then inl (iff.mp H Hp)
else inr (iff.mp (not_iff_not_of_iff H) Hp)
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definition decidable_of_decidable_of_eq (Hp : decidable p) (H : p = q) : decidable q :=
decidable_of_decidable_of_iff Hp (iff.of_eq H)
protected definition or.by_cases [Hp : decidable p] [Hq : decidable q] {A : Type}
(h : p q) (h₁ : p → A) (h₂ : q → A) : A :=
if hp : p then h₁ hp else
if hq : q then h₂ hq else
false.rec _ (or.elim h hp hq)
end
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section
variables {p q : Prop}
open decidable (rec_on inl inr)
definition decidable_and [instance] [Hp : decidable p] [Hq : decidable q] : decidable (p ∧ q) :=
if hp : p then
if hq : q then inl (and.intro hp hq)
else inr (assume H : p ∧ q, hq (and.right H))
else inr (assume H : p ∧ q, hp (and.left H))
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definition decidable_or [instance] [Hp : decidable p] [Hq : decidable q] : decidable (p q) :=
if hp : p then inl (or.inl hp) else
if hq : q then inl (or.inr hq) else
inr (or.rec hp hq)
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definition decidable_not [instance] [Hp : decidable p] : decidable (¬p) :=
if hp : p then inr (absurd hp) else inl hp
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definition decidable_implies [instance] [Hp : decidable p] [Hq : decidable q] : decidable (p → q) :=
if hp : p then
if hq : q then inl (assume H, hq)
else inr (assume H : p → q, absurd (H hp) hq)
else inl (assume Hp, absurd Hp hp)
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definition decidable_iff [instance] [Hp : decidable p] [Hq : decidable q] : decidable (p ↔ q) :=
decidable_and
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end
definition decidable_pred [reducible] {A : Type} (R : A → Prop) := Π (a : A), decidable (R a)
definition decidable_rel [reducible] {A : Type} (R : A → A → Prop) := Π (a b : A), decidable (R a b)
definition decidable_eq [reducible] (A : Type) := decidable_rel (@eq A)
definition decidable_ne [instance] {A : Type} [H : decidable_eq A] (a b : A) : decidable (a ≠ b) :=
decidable_implies
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namespace bool
theorem ff_ne_tt : ff = tt → false
| [none]
end bool
open bool
definition is_dec_eq {A : Type} (p : A → A → bool) : Prop := ∀ ⦃x y : A⦄, p x y = tt → x = y
definition is_dec_refl {A : Type} (p : A → A → bool) : Prop := ∀x, p x x = tt
open decidable
protected definition bool.has_decidable_eq [instance] : ∀a b : bool, decidable (a = b)
| ff ff := inl rfl
| ff tt := inr ff_ne_tt
| tt ff := inr (ne.symm ff_ne_tt)
| tt tt := inl rfl
definition decidable_eq_of_bool_pred {A : Type} {p : A → A → bool} (H₁ : is_dec_eq p) (H₂ : is_dec_refl p) : decidable_eq A :=
take x y : A, if Hp : p x y = tt then inl (H₁ Hp)
else inr (assume Hxy : x = y, (eq.subst Hxy Hp) (H₂ y))
theorem decidable_eq_inl_refl {A : Type} [H : decidable_eq A] (a : A) : H a a = inl (eq.refl a) :=
match H a a with
| inl e := rfl
| inr n := absurd rfl n
end
open eq.ops
theorem decidable_eq_inr_neg {A : Type} [H : decidable_eq A] {a b : A} : Π n : a ≠ b, H a b = inr n :=
assume n,
match H a b with
| inl e := absurd e n
| inr n₁ := proof_irrel n n₁ ▸ rfl
end
/- inhabited -/
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inductive inhabited [class] (A : Type) : Type :=
mk : A → inhabited A
protected definition inhabited.value {A : Type} : inhabited A → A :=
inhabited.rec (λa, a)
protected definition inhabited.destruct {A : Type} {B : Type} (H1 : inhabited A) (H2 : A → B) : B :=
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inhabited.rec H2 H1
definition default (A : Type) [H : inhabited A] : A :=
inhabited.value H
definition arbitrary [irreducible] (A : Type) [H : inhabited A] : A :=
inhabited.value H
definition Prop.is_inhabited [instance] : inhabited Prop :=
inhabited.mk true
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definition inhabited_fun [instance] (A : Type) {B : Type} [H : inhabited B] : inhabited (A → B) :=
inhabited.rec_on H (λb, inhabited.mk (λa, b))
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definition inhabited_Pi [instance] (A : Type) {B : A → Type} [H : Πx, inhabited (B x)] :
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inhabited (Πx, B x) :=
inhabited.mk (λa, !default)
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protected definition bool.is_inhabited [instance] : inhabited bool :=
inhabited.mk ff
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inductive nonempty [class] (A : Type) : Prop :=
intro : A → nonempty A
protected definition nonempty.elim {A : Type} {B : Prop} (H1 : nonempty A) (H2 : A → B) : B :=
nonempty.rec H2 H1
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theorem nonempty_of_inhabited [instance] {A : Type} [H : inhabited A] : nonempty A :=
nonempty.intro !default
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theorem nonempty_of_exists {A : Type} {P : A → Prop} : (∃x, P x) → nonempty A :=
Exists.rec (λw H, nonempty.intro w)
/- subsingleton -/
inductive subsingleton [class] (A : Type) : Prop :=
intro : (∀ a b : A, a = b) → subsingleton A
protected definition subsingleton.elim {A : Type} [H : subsingleton A] : ∀(a b : A), a = b :=
subsingleton.rec (λp, p) H
definition subsingleton_prop [instance] (p : Prop) : subsingleton p :=
subsingleton.intro (λa b, !proof_irrel)
definition subsingleton_decidable [instance] (p : Prop) : subsingleton (decidable p) :=
subsingleton.intro (λ d₁,
match d₁ with
| inl t₁ := (λ d₂,
match d₂ with
| inl t₂ := eq.rec_on (proof_irrel t₁ t₂) rfl
| inr f₂ := absurd t₁ f₂
end)
| inr f₁ := (λ d₂,
match d₂ with
| inl t₂ := absurd t₂ f₁
| inr f₂ := eq.rec_on (proof_irrel f₁ f₂) rfl
end)
end)
protected theorem rec_subsingleton {p : Prop} [H : decidable p]
{H1 : p → Type} {H2 : ¬p → Type}
[H3 : Π(h : p), subsingleton (H1 h)] [H4 : Π(h : ¬p), subsingleton (H2 h)]
: subsingleton (decidable.rec_on H H1 H2) :=
decidable.rec_on H (λh, H3 h) (λh, H4 h) --this can be proven using dependent version of "by_cases"
theorem if_pos {c : Prop} [H : decidable c] (Hc : c) {A : Type} {t e : A} : (ite c t e) = t :=
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decidable.rec
(λ Hc : c, eq.refl (@ite c (decidable.inl Hc) A t e))
(λ Hnc : ¬c, absurd Hc Hnc)
H
theorem if_neg {c : Prop} [H : decidable c] (Hnc : ¬c) {A : Type} {t e : A} : (ite c t e) = e :=
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decidable.rec
(λ Hc : c, absurd Hc Hnc)
(λ Hnc : ¬c, eq.refl (@ite c (decidable.inr Hnc) A t e))
H
theorem if_t_t [simp] (c : Prop) [H : decidable c] {A : Type} (t : A) : (ite c t t) = t :=
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decidable.rec
(λ Hc : c, eq.refl (@ite c (decidable.inl Hc) A t t))
(λ Hnc : ¬c, eq.refl (@ite c (decidable.inr Hnc) A t t))
H
theorem implies_of_if_pos {c t e : Prop} [H : decidable c] (h : ite c t e) : c → t :=
assume Hc, eq.rec_on (if_pos Hc) h
theorem implies_of_if_neg {c t e : Prop} [H : decidable c] (h : ite c t e) : ¬c → e :=
assume Hnc, eq.rec_on (if_neg Hnc) h
theorem if_ctx_congr {A : Type} {b c : Prop} [dec_b : decidable b] [dec_c : decidable c]
{x y u v : A}
(h_c : b ↔ c) (h_t : c → x = u) (h_e : ¬c → y = v) :
ite b x y = ite c u v :=
decidable.rec_on dec_b
(λ hp : b, calc
ite b x y = x : if_pos hp
... = u : h_t (iff.mp h_c hp)
... = ite c u v : if_pos (iff.mp h_c hp))
(λ hn : ¬b, calc
ite b x y = y : if_neg hn
... = v : h_e (iff.mp (not_iff_not_of_iff h_c) hn)
... = ite c u v : if_neg (iff.mp (not_iff_not_of_iff h_c) hn))
theorem if_congr {A : Type} {b c : Prop} [dec_b : decidable b] [dec_c : decidable c]
{x y u v : A}
(h_c : b ↔ c) (h_t : x = u) (h_e : y = v) :
ite b x y = ite c u v :=
@if_ctx_congr A b c dec_b dec_c x y u v h_c (λ h, h_t) (λ h, h_e)
theorem if_ctx_simp_congr {A : Type} {b c : Prop} [dec_b : decidable b] {x y u v : A}
(h_c : b ↔ c) (h_t : c → x = u) (h_e : ¬c → y = v) :
ite b x y = (@ite c (decidable_of_decidable_of_iff dec_b h_c) A u v) :=
@if_ctx_congr A b c dec_b (decidable_of_decidable_of_iff dec_b h_c) x y u v h_c h_t h_e
theorem if_simp_congr [congr] {A : Type} {b c : Prop} [dec_b : decidable b] {x y u v : A}
(h_c : b ↔ c) (h_t : x = u) (h_e : y = v) :
ite b x y = (@ite c (decidable_of_decidable_of_iff dec_b h_c) A u v) :=
@if_ctx_simp_congr A b c dec_b x y u v h_c (λ h, h_t) (λ h, h_e)
theorem if_congr_prop {b c x y u v : Prop} [dec_b : decidable b] [dec_c : decidable c]
(h_c : b ↔ c) (h_t : c → (x ↔ u)) (h_e : ¬c → (y ↔ v)) :
ite b x y ↔ ite c u v :=
decidable.rec_on dec_b
(λ hp : b, calc
ite b x y ↔ x : iff.of_eq (if_pos hp)
... ↔ u : h_t (iff.mp h_c hp)
... ↔ ite c u v : iff.of_eq (if_pos (iff.mp h_c hp)))
(λ hn : ¬b, calc
ite b x y ↔ y : iff.of_eq (if_neg hn)
... ↔ v : h_e (iff.mp (not_iff_not_of_iff h_c) hn)
... ↔ ite c u v : iff.of_eq (if_neg (iff.mp (not_iff_not_of_iff h_c) hn)))
theorem if_ctx_simp_congr_prop {b c x y u v : Prop} [dec_b : decidable b]
(h_c : b ↔ c) (h_t : c → (x ↔ u)) (h_e : ¬c → (y ↔ v)) :
ite b x y ↔ (@ite c (decidable_of_decidable_of_iff dec_b h_c) Prop u v) :=
@if_congr_prop b c x y u v dec_b (decidable_of_decidable_of_iff dec_b h_c) h_c h_t h_e
theorem if_simp_congr_prop [congr] {b c x y u v : Prop} [dec_b : decidable b]
(h_c : b ↔ c) (h_t : x ↔ u) (h_e : y ↔ v) :
ite b x y ↔ (@ite c (decidable_of_decidable_of_iff dec_b h_c) Prop u v) :=
@if_ctx_simp_congr_prop b c x y u v dec_b h_c (λ h, h_t) (λ h, h_e)
theorem dif_pos {c : Prop} [H : decidable c] (Hc : c) {A : Type} {t : c → A} {e : ¬ c → A} : dite c t e = t Hc :=
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decidable.rec
(λ Hc : c, eq.refl (@dite c (decidable.inl Hc) A t e))
(λ Hnc : ¬c, absurd Hc Hnc)
H
theorem dif_neg {c : Prop} [H : decidable c] (Hnc : ¬c) {A : Type} {t : c → A} {e : ¬ c → A} : dite c t e = e Hnc :=
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decidable.rec
(λ Hc : c, absurd Hc Hnc)
(λ Hnc : ¬c, eq.refl (@dite c (decidable.inr Hnc) A t e))
H
theorem dif_ctx_congr {A : Type} {b c : Prop} [dec_b : decidable b] [dec_c : decidable c]
{x : b → A} {u : c → A} {y : ¬b → A} {v : ¬c → A}
(h_c : b ↔ c)
(h_t : ∀ (h : c), x (iff.mpr h_c h) = u h)
(h_e : ∀ (h : ¬c), y (iff.mpr (not_iff_not_of_iff h_c) h) = v h) :
(@dite b dec_b A x y) = (@dite c dec_c A u v) :=
decidable.rec_on dec_b
(λ hp : b, calc
dite b x y = x hp : dif_pos hp
... = x (iff.mpr h_c (iff.mp h_c hp)) : proof_irrel
... = u (iff.mp h_c hp) : h_t
... = dite c u v : dif_pos (iff.mp h_c hp))
(λ hn : ¬b, let h_nc : ¬b ↔ ¬c := not_iff_not_of_iff h_c in calc
dite b x y = y hn : dif_neg hn
... = y (iff.mpr h_nc (iff.mp h_nc hn)) : proof_irrel
... = v (iff.mp h_nc hn) : h_e
... = dite c u v : dif_neg (iff.mp h_nc hn))
theorem dif_ctx_simp_congr {A : Type} {b c : Prop} [dec_b : decidable b]
{x : b → A} {u : c → A} {y : ¬b → A} {v : ¬c → A}
(h_c : b ↔ c)
(h_t : ∀ (h : c), x (iff.mpr h_c h) = u h)
(h_e : ∀ (h : ¬c), y (iff.mpr (not_iff_not_of_iff h_c) h) = v h) :
(@dite b dec_b A x y) = (@dite c (decidable_of_decidable_of_iff dec_b h_c) A u v) :=
@dif_ctx_congr A b c dec_b (decidable_of_decidable_of_iff dec_b h_c) x u y v h_c h_t h_e
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-- Remark: dite and ite are "definitionally equal" when we ignore the proofs.
theorem dite_ite_eq (c : Prop) [H : decidable c] {A : Type} (t : A) (e : A) : dite c (λh, t) (λh, e) = ite c t e :=
rfl
definition is_true (c : Prop) [H : decidable c] : Prop :=
if c then true else false
definition is_false (c : Prop) [H : decidable c] : Prop :=
if c then false else true
definition of_is_true {c : Prop} [H₁ : decidable c] (H₂ : is_true c) : c :=
decidable.rec_on H₁ (λ Hc, Hc) (λ Hnc, !false.rec (if_neg Hnc ▸ H₂))
notation `dec_trivial` := of_is_true trivial
theorem not_of_not_is_true {c : Prop} [H₁ : decidable c] (H₂ : ¬ is_true c) : ¬ c :=
if Hc : c then absurd trivial (if_pos Hc ▸ H₂) else Hc
theorem not_of_is_false {c : Prop} [H₁ : decidable c] (H₂ : is_false c) : ¬ c :=
if Hc : c then !false.rec (if_pos Hc ▸ H₂) else Hc
theorem of_not_is_false {c : Prop} [H₁ : decidable c] (H₂ : ¬ is_false c) : c :=
if Hc : c then Hc else absurd trivial (if_neg Hc ▸ H₂)
-- namespace used to collect congruence rules for "contextual simplification"
namespace contextual
attribute if_ctx_simp_congr [congr]
attribute if_ctx_simp_congr_prop [congr]
attribute dif_ctx_simp_congr [congr]
end contextual