2015-07-29 20:30:18 +00:00
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/-
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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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Authors: Leonardo de Moura, Jeremy Avigad
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-/
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2015-08-13 01:37:33 +00:00
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prelude
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import init.subtype init.funext
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2015-07-29 20:30:18 +00:00
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2015-08-13 01:37:33 +00:00
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namespace classical
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open subtype
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2015-07-29 20:30:18 +00:00
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/- the axiom -/
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-- In the presence of classical logic, we could prove this from a weaker statement:
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-- axiom indefinite_description {A : Type} {P : A->Prop} (H : ∃x, P x) : {x : A, P x}
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axiom strong_indefinite_description {A : Type} (P : A → Prop) (H : nonempty A) :
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{ x | (∃y : A, P y) → P x}
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theorem exists_true_of_nonempty {A : Type} (H : nonempty A) : ∃x : A, true :=
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nonempty.elim H (take x, exists.intro x trivial)
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noncomputable definition inhabited_of_nonempty {A : Type} (H : nonempty A) : inhabited A :=
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let u : {x | (∃y : A, true) → true} := strong_indefinite_description (λa, true) H in
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inhabited.mk (elt_of u)
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noncomputable definition inhabited_of_exists {A : Type} {P : A → Prop} (H : ∃x, P x) : inhabited A :=
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inhabited_of_nonempty (obtain w Hw, from H, nonempty.intro w)
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/- the Hilbert epsilon function -/
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noncomputable definition epsilon {A : Type} [H : nonempty A] (P : A → Prop) : A :=
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let u : {x | (∃y, P y) → P x} :=
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strong_indefinite_description P H in
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elt_of u
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theorem epsilon_spec_aux {A : Type} (H : nonempty A) (P : A → Prop) (Hex : ∃y, P y) :
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P (@epsilon A H P) :=
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let u : {x | (∃y, P y) → P x} :=
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strong_indefinite_description P H in
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have aux : (∃y, P y) → P (elt_of (strong_indefinite_description P H)), from has_property u,
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aux Hex
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theorem epsilon_spec {A : Type} {P : A → Prop} (Hex : ∃y, P y) :
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P (@epsilon A (nonempty_of_exists Hex) P) :=
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epsilon_spec_aux (nonempty_of_exists Hex) P Hex
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theorem epsilon_singleton {A : Type} (a : A) : @epsilon A (nonempty.intro a) (λx, x = a) = a :=
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epsilon_spec (exists.intro a (eq.refl a))
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noncomputable definition some {A : Type} {P : A → Prop} (H : ∃x, P x) : A :=
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@epsilon A (nonempty_of_exists H) P
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theorem some_spec {A : Type} {P : A → Prop} (H : ∃x, P x) : P (some H) :=
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epsilon_spec H
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/- the axiom of choice -/
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theorem axiom_of_choice {A : Type} {B : A → Type} {R : Πx, B x → Prop} (H : ∀x, ∃y, R x y) :
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∃f, ∀x, R x (f x) :=
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have H : ∀x, R x (some (H x)), from take x, some_spec (H x),
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exists.intro _ H
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theorem skolem {A : Type} {B : A → Type} {P : Πx, B x → Prop} :
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(∀x, ∃y, P x y) ↔ ∃f, (∀x, P x (f x)) :=
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iff.intro
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(assume H : (∀x, ∃y, P x y), axiom_of_choice H)
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(assume H : (∃f, (∀x, P x (f x))),
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take x, obtain (fw : ∀x, B x) (Hw : ∀x, P x (fw x)), from H,
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exists.intro (fw x) (Hw x))
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/-
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Prove excluded middle using Hilbert's choice
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The proof follows Diaconescu proof that shows that the axiom of choice implies the excluded middle.
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-/
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section diaconescu
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open eq.ops
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parameter p : Prop
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private definition U (x : Prop) : Prop := x = true ∨ p
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private definition V (x : Prop) : Prop := x = false ∨ p
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private noncomputable definition u := epsilon U
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private noncomputable definition v := epsilon V
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private lemma u_def : U u :=
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epsilon_spec (exists.intro true (or.inl rfl))
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private lemma v_def : V v :=
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epsilon_spec (exists.intro false (or.inl rfl))
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private lemma not_uv_or_p : ¬(u = v) ∨ p :=
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or.elim u_def
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(assume Hut : u = true,
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or.elim v_def
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(assume Hvf : v = false,
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have Hne : ¬(u = v), from Hvf⁻¹ ▸ Hut⁻¹ ▸ true_ne_false,
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or.inl Hne)
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(assume Hp : p, or.inr Hp))
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(assume Hp : p, or.inr Hp)
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private lemma p_implies_uv : p → u = v :=
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assume Hp : p,
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have Hpred : U = V, from
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funext (take x : Prop,
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have Hl : (x = true ∨ p) → (x = false ∨ p), from
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assume A, or.inr Hp,
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have Hr : (x = false ∨ p) → (x = true ∨ p), from
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assume A, or.inr Hp,
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show (x = true ∨ p) = (x = false ∨ p), from
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propext (iff.intro Hl Hr)),
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have H' : epsilon U = epsilon V, from Hpred ▸ rfl,
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show u = v, from H'
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theorem em : p ∨ ¬p :=
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have H : ¬(u = v) → ¬p, from mt p_implies_uv,
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or.elim not_uv_or_p
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(assume Hne : ¬(u = v), or.inr (H Hne))
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(assume Hp : p, or.inl Hp)
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end diaconescu
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theorem prop_complete (a : Prop) : a = true ∨ a = false :=
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or.elim (em a)
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(λ t, or.inl (propext (iff.intro (λ h, trivial) (λ h, t))))
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(λ f, or.inr (propext (iff.intro (λ h, absurd h f) (λ h, false.elim h))))
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definition eq_true_or_eq_false := prop_complete
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section aux
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open eq.ops
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theorem cases_true_false (P : Prop → Prop) (H1 : P true) (H2 : P false) (a : Prop) : P a :=
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or.elim (prop_complete a)
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(assume Ht : a = true, Ht⁻¹ ▸ H1)
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(assume Hf : a = false, Hf⁻¹ ▸ H2)
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theorem cases_on (a : Prop) {P : Prop → Prop} (H1 : P true) (H2 : P false) : P a :=
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cases_true_false P H1 H2 a
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-- this supercedes by_cases in decidable
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definition by_cases {p q : Prop} (Hpq : p → q) (Hnpq : ¬p → q) : q :=
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or.elim (em p) (assume Hp, Hpq Hp) (assume Hnp, Hnpq Hnp)
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-- this supercedes by_contradiction in decidable
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theorem by_contradiction {p : Prop} (H : ¬p → false) : p :=
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by_cases
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(assume H1 : p, H1)
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(assume H1 : ¬p, false.rec _ (H H1))
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theorem eq_false_or_eq_true (a : Prop) : a = false ∨ a = true :=
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cases_true_false (λ x, x = false ∨ x = true)
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(or.inr rfl)
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(or.inl rfl)
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a
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theorem eq.of_iff {a b : Prop} (H : a ↔ b) : a = b :=
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iff.elim (assume H1 H2, propext (iff.intro H1 H2)) H
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theorem iff_eq_eq {a b : Prop} : (a ↔ b) = (a = b) :=
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propext (iff.intro
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(assume H, eq.of_iff H)
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(assume H, iff.of_eq H))
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end aux
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/- All propositions are decidable -/
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2015-08-13 01:37:33 +00:00
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open decidable
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2015-07-29 20:30:18 +00:00
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noncomputable definition decidable_inhabited [instance] [priority 0] (a : Prop) : inhabited (decidable a) :=
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inhabited_of_nonempty
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(or.elim (em a)
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(assume Ha, nonempty.intro (inl Ha))
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(assume Hna, nonempty.intro (inr Hna)))
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noncomputable definition prop_decidable [instance] [priority 0] (a : Prop) : decidable a :=
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arbitrary (decidable a)
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2015-08-13 01:37:33 +00:00
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noncomputable definition type_decidable (A : Type) : sum A (A → false) :=
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2015-07-29 20:30:18 +00:00
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match prop_decidable (nonempty A) with
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| inl Hp := sum.inl (inhabited.value (inhabited_of_nonempty Hp))
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| inr Hn := sum.inr (λ a, absurd (nonempty.intro a) Hn)
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end
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2015-08-13 00:06:15 +00:00
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end classical
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