lean2/library/init/logic.lean

618 lines
19 KiB
Text
Raw Normal View History

2014-12-01 04:34:12 +00:00
/-
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
-- -----------
definition imp (a b : Prop) : Prop := a → b
-- make c explicit and rename to false.elim
theorem false_elim {c : Prop} (H : false) : c :=
false.rec c H
definition trivial := true.intro
definition not (a : Prop) := a → false
prefix `¬` := not
definition absurd {a : Prop} {b : Type} (H1 : a) (H2 : ¬a) : b :=
false.rec b (H2 H1)
theorem mt {a b : Prop} (H1 : a → b) (H2 : ¬b) : ¬a :=
assume Ha : a, absurd (H1 Ha) H2
-- not
-- ---
theorem not_false : ¬false :=
assume H : false, H
theorem not_not_intro {a : Prop} (Ha : a) : ¬¬a :=
assume Hna : ¬a, absurd Ha Hna
theorem not_intro {a : Prop} (H : a → false) : ¬a := H
theorem not_elim {a : Prop} (H1 : ¬a) (H2 : a) : false := H1 H2
theorem not_implies_left {a b : Prop} (H : ¬(a → b)) : ¬¬a :=
assume Hna : ¬a, absurd (assume Ha : a, absurd Ha Hna) H
theorem not_implies_right {a b : Prop} (H : ¬(a → b)) : ¬b :=
assume Hb : b, absurd (assume Ha : a, Hb) H
-- eq
-- --
notation a = b := eq a b
definition rfl {A : Type} {a : A} := eq.refl a
-- proof irrelevance is built in
theorem proof_irrel {a : Prop} (H₁ H₂ : a) : H₁ = H₂ :=
rfl
namespace eq
variables {A : Type}
variables {a b c a': A}
definition drec_on {B : Πa' : A, a = a' → Type} (H₁ : a = a') (H₂ : B a (refl a)) : B a' H₁ :=
eq.rec (λH₁ : a = a, show B a H₁, from H₂) H₁ H₁
theorem id_refl (H₁ : a = a) : H₁ = (eq.refl a) :=
rfl
theorem irrel (H₁ H₂ : a = b) : H₁ = H₂ :=
!proof_irrel
theorem subst {P : A → Prop} (H₁ : a = b) (H₂ : P a) : P b :=
rec H₂ H₁
theorem trans (H₁ : a = b) (H₂ : b = c) : a = c :=
subst H₂ H₁
theorem symm (H : a = b) : b = a :=
subst H (refl a)
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
end ops
variable {p : Prop}
open ops
theorem true_elim (H : p = true) : p :=
H⁻¹ ▸ trivial
theorem false_elim (H : p = false) : ¬p :=
assume Hp, H ▸ Hp
end eq
calc_subst eq.subst
calc_refl eq.refl
calc_trans eq.trans
calc_symm eq.symm
-- ne
-- --
definition ne {A : Type} (a b : A) := ¬(a = b)
notation a ≠ b := ne a b
namespace ne
open eq.ops
variable {A : Type}
variables {a b : A}
theorem intro : (a = b → false) → a ≠ b :=
assume H, H
theorem elim : a ≠ b → a = b → false :=
assume H₁ H₂, H₁ H₂
theorem irrefl : a ≠ a → false :=
assume H, H rfl
theorem symm : a ≠ b → b ≠ a :=
assume (H : a ≠ b) (H₁ : b = a), H (H₁⁻¹)
end ne
section
open eq.ops
variables {A : Type} {a b c : A}
theorem false.of_ne : a ≠ a → false :=
assume H, H rfl
theorem ne.of_eq_of_ne : a = b → b ≠ c → a ≠ c :=
assume H₁ H₂, H₁⁻¹ ▸ H₂
theorem ne.of_ne_of_eq : a ≠ b → b = c → a ≠ c :=
assume H₁ H₂, H₂ ▸ H₁
end
calc_trans ne.of_eq_of_ne
calc_trans ne.of_ne_of_eq
infixl `==`:50 := heq
namespace heq
universe variable u
variables {A B C : Type.{u}} {a a' : A} {b b' : B} {c : C}
definition to_eq (H : a == a') : a = a' :=
have H₁ : ∀ (Ht : A = A), eq.rec_on Ht a = a, from
λ Ht, eq.refl (eq.rec_on Ht a),
heq.rec_on H H₁ (eq.refl A)
definition elim {A : Type} {a : A} {P : A → Type} {b : A} (H₁ : a == b) (H₂ : P a) : P b :=
eq.rec_on (to_eq H₁) H₂
theorem drec_on {C : Π {B : Type} (b : B), a == b → Type} (H₁ : a == b) (H₂ : C a (refl a)) : C b H₁ :=
rec (λ H₁ : a == a, show C a H₁, from H₂) H₁ H₁
theorem subst {P : ∀T : Type, T → Prop} (H₁ : a == b) (H₂ : P A a) : P B b :=
rec_on H₁ H₂
theorem symm (H : a == b) : b == a :=
rec_on H (refl a)
definition type_eq (H : a == b) : A = B :=
heq.rec_on H (eq.refl A)
theorem from_eq (H : a = a') : a == a' :=
eq.subst H (refl a)
theorem trans (H₁ : a == b) (H₂ : b == c) : a == c :=
subst H₂ H₁
theorem trans_left (H₁ : a == b) (H₂ : b = b') : a == b' :=
trans H₁ (from_eq H₂)
theorem trans_right (H₁ : a = a') (H₂ : a' == b) : a == b :=
trans (from_eq H₁) H₂
theorem true_elim {a : Prop} (H : a == true) : a :=
eq.true_elim (heq.to_eq H)
end heq
calc_trans heq.trans
calc_trans heq.trans_left
calc_trans heq.trans_right
calc_symm heq.symm
theorem eq_rec_heq {A : Type} {P : A → Type} {a a' : A} (H : a = a') (p : P a) : eq.rec_on H p == p :=
eq.drec_on H !heq.refl
section
universe variables u v
variables {A A' B C : Type.{u}} {P P' : A → Type.{v}} {a a' : A} {b : B}
theorem hcongr_fun {f : Π x, P x} {f' : Π x, P' x} (a : A) (H₁ : f == f') (H₂ : P = P') : f a == f' a :=
have aux : ∀ (f : Π x, P x) (f' : Π x, P x), f == f' → f a == f' a, from
take f f' H, heq.to_eq H ▸ heq.refl (f a),
(H₂ ▸ aux) f f' H₁
theorem hcongr {P' : A' → Type} {f : Π a, P a} {f' : Π a', P' a'} {a : A} {a' : A'}
(Hf : f == f') (HP : P == P') (Ha : a == a') : f a == f' a' :=
have H1 : ∀ (B P' : A → Type) (f : Π x, P x) (f' : Π x, P' x), f == f' → (λx, P x) == (λx, P' x)
→ f a == f' a, from
take P P' f f' Hf HB, hcongr_fun a Hf (heq.to_eq HB),
have H2 : ∀ (B : A → Type) (P' : A' → Type) (f : Π x, P x) (f' : Π x, P' x),
f == f' → (λx, P x) == (λx, P' x) → f a == f' a', from heq.subst Ha H1,
H2 P P' f f' Hf HP
theorem hcongr_arg (f : Πx, P x) {a b : A} (H : a = b) : f a == f b :=
H ▸ (heq.refl (f a))
end
section
variables {A : Type} {B : A → Type} {C : Πa, B a → Type} {D : Πa b, C a b → Type}
variables {a a' : A} {b : B a} {b' : B a'} {c : C a b} {c' : C a' b'}
theorem hcongr_arg2 (f : Πa b, C a b) (Ha : a = a') (Hb : b == b') : f a b == f a' b' :=
hcongr (hcongr_arg f Ha) (hcongr_arg C Ha) Hb
theorem hcongr_arg3 (f : Πa b c, D a b c) (Ha : a = a') (Hb : b == b') (Hc : c == c')
: f a b c == f a' b' c' :=
hcongr (hcongr_arg2 f Ha Hb) (hcongr_arg2 D Ha Hb) Hc
end
-- and
-- ---
notation a /\ b := and a b
notation a ∧ b := and a b
variables {a b c d : Prop}
namespace and
theorem elim (H₁ : a ∧ b) (H₂ : a → b → c) : c :=
rec H₂ H₁
definition elim_left (H : a ∧ b) : a :=
rec (λa b, a) H
definition elim_right (H : a ∧ b) : b :=
rec (λa b, b) H
theorem swap (H : a ∧ b) : b ∧ a :=
intro (elim_right H) (elim_left H)
definition not_left (b : Prop) (Hna : ¬a) : ¬(a ∧ b) :=
assume H : a ∧ b, absurd (elim_left H) Hna
definition not_right (a : Prop) {b : Prop} (Hnb : ¬b) : ¬(a ∧ b) :=
assume H : a ∧ b, absurd (elim_right H) Hnb
theorem imp_and (H₁ : a ∧ b) (H₂ : a → c) (H₃ : b → d) : c ∧ d :=
elim H₁ (assume Ha : a, assume Hb : b, intro (H₂ Ha) (H₃ Hb))
theorem imp_left (H₁ : a ∧ c) (H : a → b) : b ∧ c :=
elim H₁ (assume Ha : a, assume Hc : c, intro (H Ha) Hc)
theorem imp_right (H₁ : c ∧ a) (H : a → b) : c ∧ b :=
elim H₁ (assume Hc : c, assume Ha : a, intro Hc (H Ha))
end and
-- or
-- --
notation a `\/` b := or a b
notation a b := or a b
namespace or
definition inl (Ha : a) : a b :=
intro_left b Ha
definition inr (Hb : b) : a b :=
intro_right a Hb
theorem elim (H₁ : a b) (H₂ : a → c) (H₃ : b → c) : c :=
rec H₂ H₃ H₁
theorem elim3 (H : a b c) (Ha : a → d) (Hb : b → d) (Hc : c → d) : d :=
elim H Ha (assume H₂, elim H₂ Hb Hc)
theorem resolve_right (H₁ : a b) (H₂ : ¬a) : b :=
elim H₁ (assume Ha, absurd Ha H₂) (assume Hb, Hb)
theorem resolve_left (H₁ : a b) (H₂ : ¬b) : a :=
elim H₁ (assume Ha, Ha) (assume Hb, absurd Hb H₂)
theorem swap (H : a b) : b a :=
elim H (assume Ha, inr Ha) (assume Hb, inl Hb)
definition not_intro (Hna : ¬a) (Hnb : ¬b) : ¬(a b) :=
assume H : a b, or.rec_on H
(assume Ha, absurd Ha Hna)
(assume Hb, absurd Hb Hnb)
theorem imp_or (H₁ : a b) (H₂ : a → c) (H₃ : b → d) : c d :=
elim H₁
(assume Ha : a, inl (H₂ Ha))
(assume Hb : b, inr (H₃ Hb))
theorem imp_or_left (H₁ : a c) (H : a → b) : b c :=
elim H₁
(assume H₂ : a, inl (H H₂))
(assume H₂ : c, inr H₂)
theorem imp_or_right (H₁ : c a) (H : a → b) : c b :=
elim H₁
(assume H₂ : c, inl H₂)
(assume H₂ : a, inr (H H₂))
end or
theorem not_not_em {p : Prop} : ¬¬(p ¬p) :=
assume not_em : ¬(p ¬p),
have Hnp : ¬p, from
assume Hp : p, absurd (or.inl Hp) not_em,
absurd (or.inr Hnp) not_em
-- iff
-- ---
definition iff (a b : Prop) := (a → b) ∧ (b → a)
notation a <-> b := iff a b
notation a ↔ b := iff a b
namespace iff
definition def : (a ↔ b) = ((a → b) ∧ (b → a)) :=
rfl
definition intro (H₁ : a → b) (H₂ : b → a) : a ↔ b :=
and.intro H₁ H₂
definition elim (H₁ : (a → b) → (b → a) → c) (H₂ : a ↔ b) : c :=
and.rec H₁ H₂
definition elim_left (H : a ↔ b) : a → b :=
elim (assume H₁ H₂, H₁) H
definition mp := @elim_left
definition elim_right (H : a ↔ b) : b → a :=
elim (assume H₁ H₂, H₂) H
definition flip_sign (H₁ : a ↔ b) : ¬a ↔ ¬b :=
intro
(assume Hna, mt (elim_right H₁) Hna)
(assume Hnb, mt (elim_left H₁) Hnb)
definition refl (a : Prop) : a ↔ a :=
intro (assume H, H) (assume H, H)
definition rfl {a : Prop} : a ↔ a :=
refl a
theorem trans (H₁ : a ↔ b) (H₂ : b ↔ c) : a ↔ c :=
intro
(assume Ha, elim_left H₂ (elim_left H₁ Ha))
(assume Hc, elim_right H₁ (elim_right H₂ Hc))
theorem symm (H : a ↔ b) : b ↔ a :=
intro
(assume Hb, elim_right H Hb)
(assume Ha, elim_left H Ha)
theorem true_elim (H : a ↔ true) : a :=
mp (symm H) trivial
theorem false_elim (H : a ↔ false) : ¬a :=
assume Ha : a, mp H Ha
open eq.ops
theorem of_eq {a b : Prop} (H : a = b) : a ↔ b :=
iff.intro (λ Ha, H ▸ Ha) (λ Hb, H⁻¹ ▸ Hb)
end iff
calc_refl iff.refl
calc_trans iff.trans
-- comm and assoc for and / or
-- ---------------------------
namespace and
theorem comm : a ∧ b ↔ b ∧ a :=
iff.intro (λH, swap H) (λH, swap H)
theorem assoc : (a ∧ b) ∧ c ↔ a ∧ (b ∧ c) :=
iff.intro
(assume H, intro
(elim_left (elim_left H))
(intro (elim_right (elim_left H)) (elim_right H)))
(assume H, intro
(intro (elim_left H) (elim_left (elim_right H)))
(elim_right (elim_right H)))
end and
namespace or
theorem comm : a b ↔ b a :=
iff.intro (λH, swap H) (λH, swap H)
theorem assoc : (a b) c ↔ a (b c) :=
iff.intro
(assume H, elim H
(assume H₁, elim H₁
(assume Ha, inl Ha)
(assume Hb, inr (inl Hb)))
(assume Hc, inr (inr Hc)))
(assume H, elim H
(assume Ha, (inl (inl Ha)))
(assume H₁, elim H₁
(assume Hb, inl (inr Hb))
(assume Hc, inr Hc)))
end or
inductive Exists {A : Type} (P : A → Prop) : Prop :=
intro : ∀ (a : A), P a → Exists P
definition exists_intro := @Exists.intro
notation `exists` binders `,` r:(scoped P, Exists P) := r
notation `∃` binders `,` r:(scoped P, Exists P) := r
theorem exists_elim {A : Type} {p : A → Prop} {B : Prop} (H1 : ∃x, p x) (H2 : ∀ (a : A) (H : p a), B) : B :=
Exists.rec H2 H1
definition exists_unique {A : Type} (p : A → Prop) :=
∃x, p x ∧ ∀y, p y → y = x
notation `∃!` binders `,` r:(scoped P, exists_unique P) := r
theorem exists_unique_intro {A : Type} {p : A → Prop} (w : A) (H1 : p w) (H2 : ∀y, p y → y = w) : ∃!x, p x :=
exists_intro w (and.intro H1 H2)
theorem exists_unique_elim {A : Type} {p : A → Prop} {b : Prop}
(H2 : ∃!x, p x) (H1 : ∀x, p x → (∀y, p y → y = x) → b) : b :=
obtain w Hw, from H2,
H1 w (and.elim_left Hw) (and.elim_right Hw)
inductive decidable [class] (p : Prop) : Type :=
inl : p → decidable p,
inr : ¬p → decidable p
definition true.decidable [instance] : decidable true :=
decidable.inl trivial
definition false.decidable [instance] : decidable false :=
decidable.inr not_false
namespace decidable
variables {p q : Prop}
definition rec_on_true [H : decidable p] {H1 : p → Type} {H2 : ¬p → Type} (H3 : p) (H4 : H1 H3)
: rec_on H H1 H2 :=
rec_on H (λh, H4) (λh, false.rec _ (h H3))
definition rec_on_false [H : decidable p] {H1 : p → Type} {H2 : ¬p → Type} (H3 : ¬p) (H4 : H2 H3)
: rec_on H H1 H2 :=
rec_on H (λh, false.rec _ (H3 h)) (λh, H4)
definition by_cases {q : Type} [C : decidable p] (Hpq : p → q) (Hnpq : ¬p → q) : q :=
rec_on C (assume Hp, Hpq Hp) (assume Hnp, Hnpq Hnp)
theorem em (p : Prop) [H : decidable p] : p ¬p :=
by_cases (λ Hp, or.inl Hp) (λ Hnp, or.inr Hnp)
theorem by_contradiction [Hp : decidable p] (H : ¬p → false) : p :=
by_cases
(assume H1 : p, H1)
(assume H1 : ¬p, false_elim (H H1))
definition decidable_iff_equiv (Hp : decidable p) (H : p ↔ q) : decidable q :=
rec_on Hp
(assume Hp : p, inl (iff.elim_left H Hp))
(assume Hnp : ¬p, inr (iff.elim_left (iff.flip_sign H) Hnp))
definition decidable_eq_equiv (Hp : decidable p) (H : p = q) : decidable q :=
decidable_iff_equiv Hp (iff.of_eq H)
end decidable
section
variables {p q : Prop}
open decidable (rec_on inl inr)
definition and.decidable [instance] (Hp : decidable p) (Hq : decidable q) : decidable (p ∧ q) :=
rec_on Hp
(assume Hp : p, rec_on Hq
(assume Hq : q, inl (and.intro Hp Hq))
(assume Hnq : ¬q, inr (and.not_right p Hnq)))
(assume Hnp : ¬p, inr (and.not_left q Hnp))
definition or.decidable [instance] (Hp : decidable p) (Hq : decidable q) : decidable (p q) :=
rec_on Hp
(assume Hp : p, inl (or.inl Hp))
(assume Hnp : ¬p, rec_on Hq
(assume Hq : q, inl (or.inr Hq))
(assume Hnq : ¬q, inr (or.not_intro Hnp Hnq)))
definition not.decidable [instance] (Hp : decidable p) : decidable (¬p) :=
rec_on Hp
(assume Hp, inr (not_not_intro Hp))
(assume Hnp, inl Hnp)
definition implies.decidable [instance] (Hp : decidable p) (Hq : decidable q) : decidable (p → q) :=
rec_on Hp
(assume Hp : p, rec_on Hq
(assume Hq : q, inl (assume H, Hq))
(assume Hnq : ¬q, inr (assume H : p → q, absurd (H Hp) Hnq)))
(assume Hnp : ¬p, inl (assume Hp, absurd Hp Hnp))
definition iff.decidable [instance] (Hp : decidable p) (Hq : decidable q) : decidable (p ↔ q) := _
end
definition decidable_pred {A : Type} (R : A → Prop) := Π (a : A), decidable (R a)
definition decidable_rel {A : Type} (R : A → A → Prop) := Π (a b : A), decidable (R a b)
definition decidable_eq (A : Type) := decidable_rel (@eq A)
inductive inhabited [class] (A : Type) : Type :=
mk : A → inhabited A
namespace inhabited
protected definition destruct {A : Type} {B : Type} (H1 : inhabited A) (H2 : A → B) : B :=
inhabited.rec H2 H1
definition Prop_inhabited [instance] : inhabited Prop :=
mk true
definition fun_inhabited [instance] (A : Type) {B : Type} (H : inhabited B) : inhabited (A → B) :=
destruct H (λb, mk (λa, b))
definition dfun_inhabited [instance] (A : Type) {B : A → Type} (H : Πx, inhabited (B x)) :
inhabited (Πx, B x) :=
mk (λa, destruct (H a) (λb, b))
definition default (A : Type) [H : inhabited A] : A := destruct H (take a, a)
end inhabited
inductive nonempty [class] (A : Type) : Prop :=
intro : A → nonempty A
namespace nonempty
protected definition elim {A : Type} {B : Prop} (H1 : nonempty A) (H2 : A → B) : B :=
rec H2 H1
theorem inhabited_imp_nonempty [instance] {A : Type} (H : inhabited A) : nonempty A :=
intro (inhabited.default A)
end nonempty
definition ite (c : Prop) [H : decidable c] {A : Type} (t e : A) : A :=
decidable.rec_on H (λ Hc, t) (λ Hnc, e)
notation `if` c `then` t:45 `else` e:45 := ite c t e
definition if_pos {c : Prop} [H : decidable c] (Hc : c) {A : Type} {t e : A} : (if c then t else e) = t :=
decidable.rec
(λ Hc : c, eq.refl (@ite c (decidable.inl Hc) A t e))
(λ Hnc : ¬c, absurd Hc Hnc)
H
definition if_neg {c : Prop} [H : decidable c] (Hnc : ¬c) {A : Type} {t e : A} : (if c then t else e) = e :=
decidable.rec
(λ Hc : c, absurd Hc Hnc)
(λ Hnc : ¬c, eq.refl (@ite c (decidable.inr Hnc) A t e))
H
definition if_t_t (c : Prop) [H : decidable c] {A : Type} (t : A) : (if c then t else t) = t :=
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
definition if_true {A : Type} (t e : A) : (if true then t else e) = t :=
if_pos trivial
definition if_false {A : Type} (t e : A) : (if false then t else e) = e :=
if_neg not_false
theorem if_cond_congr {c₁ c₂ : Prop} [H₁ : decidable c₁] [H₂ : decidable c₂] (Heq : c₁ ↔ c₂) {A : Type} (t e : A)
: (if c₁ then t else e) = (if c₂ then t else e) :=
decidable.rec_on H₁
(λ Hc₁ : c₁, decidable.rec_on H₂
(λ Hc₂ : c₂, if_pos Hc₁ ⬝ (if_pos Hc₂)⁻¹)
(λ Hnc₂ : ¬c₂, absurd (iff.elim_left Heq Hc₁) Hnc₂))
(λ Hnc₁ : ¬c₁, decidable.rec_on H₂
(λ Hc₂ : c₂, absurd (iff.elim_right Heq Hc₂) Hnc₁)
(λ Hnc₂ : ¬c₂, if_neg Hnc₁ ⬝ (if_neg Hnc₂)⁻¹))
theorem if_congr_aux {c₁ c₂ : Prop} [H₁ : decidable c₁] [H₂ : decidable c₂] {A : Type} {t₁ t₂ e₁ e₂ : A}
(Hc : c₁ ↔ c₂) (Ht : t₁ = t₂) (He : e₁ = e₂) :
(if c₁ then t₁ else e₁) = (if c₂ then t₂ else e₂) :=
Ht ▸ He ▸ (if_cond_congr Hc t₁ e₁)
theorem if_congr {c₁ c₂ : Prop} [H₁ : decidable c₁] {A : Type} {t₁ t₂ e₁ e₂ : A} (Hc : c₁ ↔ c₂) (Ht : t₁ = t₂) (He : e₁ = e₂) :
(if c₁ then t₁ else e₁) = (@ite c₂ (decidable.decidable_iff_equiv H₁ Hc) A t₂ e₂) :=
have H2 [visible] : decidable c₂, from (decidable.decidable_iff_equiv H₁ Hc),
if_congr_aux Hc Ht He
-- 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} (t : c → A) (e : ¬ c → A) : A :=
decidable.rec_on H (λ Hc, t Hc) (λ Hnc, e Hnc)
notation `dif` c `then` t:45 `else` e:45 := dite c t e
definition dif_pos {c : Prop} [H : decidable c] (Hc : c) {A : Type} {t : c → A} {e : ¬ c → A} : (dif c then t else e) = t Hc :=
decidable.rec
(λ Hc : c, eq.refl (@dite c (decidable.inl Hc) A t e))
(λ Hnc : ¬c, absurd Hc Hnc)
H
definition dif_neg {c : Prop} [H : decidable c] (Hnc : ¬c) {A : Type} {t : c → A} {e : ¬ c → A} : (dif c then t else e) = e Hnc :=
decidable.rec
(λ Hc : c, absurd Hc Hnc)
(λ Hnc : ¬c, eq.refl (@dite c (decidable.inr Hnc) A t e))
H
-- 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