import macros universe U ≥ 1 variable Bool : Type -- The following builtin declarations can be removed as soon as Lean supports inductive datatypes and match expressions builtin true : Bool builtin false : Bool definition TypeU := (Type U) definition not (a : Bool) := a → false notation 40 ¬ _ : not definition or (a b : Bool) := ¬ a → b infixr 30 || : or infixr 30 \/ : or infixr 30 ∨ : or definition and (a b : Bool) := ¬ (a → ¬ b) definition implies (a b : Bool) := a → b infixr 35 && : and infixr 35 /\ : and infixr 35 ∧ : and -- The Lean parser has special treatment for the constant exists. -- It allows us to write -- exists x y : A, P x y and ∃ x y : A, P x y -- as syntax sugar for -- exists A (fun x : A, exists A (fun y : A, P x y)) -- That is, it treats the exists as an extra binder such as fun and forall. -- It also provides an alias (Exists) that should be used when we -- want to treat exists as a constant. definition Exists (A : TypeU) (P : A → Bool) := ¬ (∀ x : A, ¬ (P x)) definition eq {A : TypeU} (a b : A) := a == b infix 50 = : eq definition neq {A : TypeU} (a b : A) := ¬ (a = b) infix 50 ≠ : neq theorem em (a : Bool) : a ∨ ¬ a := assume Hna : ¬ a, Hna axiom case (P : Bool → Bool) (H1 : P true) (H2 : P false) (a : Bool) : P a axiom refl {A : TypeU} (a : A) : a = a axiom subst {A : TypeU} {a b : A} {P : A → Bool} (H1 : P a) (H2 : a = b) : P b -- Function extensionality axiom funext {A : TypeU} {B : A → TypeU} {f g : ∀ x : A, B x} (H : ∀ x : A, f x == g x) : f == g -- Forall extensionality axiom allext {A : TypeU} {B C : A → TypeU} (H : ∀ x : A, B x == C x) : (∀ x : A, B x) == (∀ x : A, C x) -- Alias for subst where we can provide P explicitly, but keep A,a,b implicit theorem substp {A : TypeU} {a b : A} (P : A → Bool) (H1 : P a) (H2 : a = b) : P b := subst H1 H2 -- We will mark not as opaque later theorem not_intro {a : Bool} (H : a → false) : ¬ a := H theorem eta {A : TypeU} {B : A → TypeU} (f : ∀ x : A, B x) : (λ x : A, f x) = f := funext (λ x : A, refl (f x)) theorem trivial : true := refl true theorem absurd {a : Bool} (H1 : a) (H2 : ¬ a) : false := H2 H1 theorem eqmp {a b : Bool} (H1 : a = b) (H2 : a) : b := subst H2 H1 infixl 100 <| : eqmp infixl 100 ◂ : eqmp theorem boolcomplete (a : Bool) : a = true ∨ a = false := case (λ x, x = true ∨ x = false) trivial trivial a theorem false_elim (a : Bool) (H : false) : a := case (λ x, x) trivial H a theorem imp_trans {a b c : Bool} (H1 : a → b) (H2 : b → c) : a → c := assume Ha, H2 (H1 Ha) theorem imp_eq_trans {a b c : Bool} (H1 : a → b) (H2 : b = c) : a → c := assume Ha, H2 ◂ (H1 Ha) theorem eq_imp_trans {a b c : Bool} (H1 : a = b) (H2 : b → c) : a → c := assume Ha, H2 (H1 ◂ Ha) theorem not_not_eq (a : Bool) : (¬ ¬ a) = a := case (λ x, (¬ ¬ x) = x) trivial trivial a theorem not_not_elim {a : Bool} (H : ¬ ¬ a) : a := (not_not_eq a) ◂ H theorem mt {a b : Bool} (H1 : a → b) (H2 : ¬ b) : ¬ a := assume Ha : a, absurd (H1 Ha) H2 theorem contrapos {a b : Bool} (H : a → b) : ¬ b → ¬ a := assume Hnb : ¬ b, mt H Hnb theorem absurd_elim {a : Bool} (b : Bool) (H1 : a) (H2 : ¬ a) : b := false_elim b (absurd H1 H2) theorem not_imp_eliml {a b : Bool} (Hnab : ¬ (a → b)) : a := not_not_elim (have ¬ ¬ a : assume Hna : ¬ a, absurd (assume Ha : a, absurd_elim b Ha Hna) Hnab) theorem not_imp_elimr {a b : Bool} (H : ¬ (a → b)) : ¬ b := assume Hb : b, absurd (assume Ha : a, Hb) H theorem resolve1 {a b : Bool} (H1 : a ∨ b) (H2 : ¬ a) : b := H1 H2 -- Recall that and is defined as ¬ (a → ¬ b) theorem and_intro {a b : Bool} (H1 : a) (H2 : b) : a ∧ b := assume H : a → ¬ b, absurd H2 (H H1) theorem and_eliml {a b : Bool} (H : a ∧ b) : a := not_imp_eliml H theorem and_elimr {a b : Bool} (H : a ∧ b) : b := not_not_elim (not_imp_elimr H) -- Recall that or is defined as ¬ a → b theorem or_introl {a : Bool} (H : a) (b : Bool) : a ∨ b := assume H1 : ¬ a, absurd_elim b H H1 theorem or_intror {b : Bool} (a : Bool) (H : b) : a ∨ b := assume H1 : ¬ a, H theorem or_elim {a b c : Bool} (H1 : a ∨ b) (H2 : a → c) (H3 : b → c) : c := not_not_elim (assume H : ¬ c, absurd (have c : H3 (have b : resolve1 H1 (have ¬ a : (mt (assume Ha : a, H2 Ha) H)))) H) theorem refute {a : Bool} (H : ¬ a → false) : a := or_elim (em a) (λ H1 : a, H1) (λ H1 : ¬ a, false_elim a (H H1)) theorem symm {A : TypeU} {a b : A} (H : a = b) : b = a := subst (refl a) H theorem trans {A : TypeU} {a b c : A} (H1 : a = b) (H2 : b = c) : a = c := subst H1 H2 infixl 100 ⋈ : trans theorem ne_symm {A : TypeU} {a b : A} (H : a ≠ b) : b ≠ a := assume H1 : b = a, H (symm H1) theorem eq_ne_trans {A : TypeU} {a b c : A} (H1 : a = b) (H2 : b ≠ c) : a ≠ c := subst H2 (symm H1) theorem ne_eq_trans {A : TypeU} {a b c : A} (H1 : a ≠ b) (H2 : b = c) : a ≠ c := subst H1 H2 theorem eqt_elim {a : Bool} (H : a = true) : a := (symm H) ◂ trivial theorem eqf_elim {a : Bool} (H : a = false) : ¬ a := not_intro (λ Ha : a, H ◂ Ha) theorem congr1 {A : TypeU} {B : A → TypeU} {f g : ∀ x : A, B x} (a : A) (H : f = g) : f a = g a := substp (fun h : (∀ x : A, B x), f a = h a) (refl (f a)) H -- We must use heterogenous equality in this theorem because (f a) : (B a) and (f b) : (B b) theorem congr2 {A : TypeU} {B : A → TypeU} {a b : A} (f : ∀ x : A, B x) (H : a = b) : f a == f b := substp (fun x : A, f a == f x) (refl (f a)) H theorem congr {A : TypeU} {B : A → TypeU} {f g : ∀ x : A, B x} {a b : A} (H1 : f = g) (H2 : a = b) : f a == g b := subst (congr2 f H2) (congr1 b H1) -- Simpler version of congr2 theorem for arrows (i.e., non-dependent types) theorem scongr2 {A B : TypeU} {a b : A} (f : A → B) (H : a = b) : f a = f b := substp (fun x : A, f a = f x) (refl (f a)) H -- Simpler version of congr theorem for arrows (i.e., non-dependent types) theorem scongr {A B : TypeU} {f g : A → B} {a b : A} (H1 : f = g) (H2 : a = b) : f a = g b := subst (scongr2 f H2) (congr1 b H1) -- Recall that exists is defined as ¬ ∀ x : A, ¬ P x theorem exists_elim {A : TypeU} {P : A → Bool} {B : Bool} (H1 : Exists A P) (H2 : ∀ (a : A) (H : P a), B) : B := refute (λ R : ¬ B, absurd (take a : A, mt (assume H : P a, H2 a H) R) H1) theorem exists_intro {A : TypeU} {P : A → Bool} (a : A) (H : P a) : Exists A P := assume H1 : (∀ x : A, ¬ P x), absurd H (H1 a) theorem boolext {a b : Bool} (Hab : a → b) (Hba : b → a) : a = b := or_elim (boolcomplete a) (λ Hat : a = true, or_elim (boolcomplete b) (λ Hbt : b = true, trans Hat (symm Hbt)) (λ Hbf : b = false, false_elim (a = b) (subst (Hab (eqt_elim Hat)) Hbf))) (λ Haf : a = false, or_elim (boolcomplete b) (λ Hbt : b = true, false_elim (a = b) (subst (Hba (eqt_elim Hbt)) Haf)) (λ Hbf : b = false, trans Haf (symm Hbf))) theorem iff_intro {a b : Bool} (Hab : a → b) (Hba : b → a) : a = b := boolext Hab Hba theorem eqt_intro {a : Bool} (H : a) : a = true := boolext (assume H1 : a, trivial) (assume H2 : true, H) theorem eqf_intro {a : Bool} (H : ¬ a) : a = false := boolext (assume H1 : a, absurd H1 H) (assume H2 : false, false_elim a H2) theorem neq_elim {A : TypeU} {a b : A} (H : a ≠ b) : (a = b) = false := eqf_intro H theorem or_comm (a b : Bool) : (a ∨ b) = (b ∨ a) := boolext (assume H, or_elim H (λ H1, or_intror b H1) (λ H2, or_introl H2 a)) (assume H, or_elim H (λ H1, or_intror a H1) (λ H2, or_introl H2 b)) theorem or_assoc (a b c : Bool) : ((a ∨ b) ∨ c) = (a ∨ (b ∨ c)) := boolext (assume H : (a ∨ b) ∨ c, or_elim H (λ H1 : a ∨ b, or_elim H1 (λ Ha : a, or_introl Ha (b ∨ c)) (λ Hb : b, or_intror a (or_introl Hb c))) (λ Hc : c, or_intror a (or_intror b Hc))) (assume H : a ∨ (b ∨ c), or_elim H (λ Ha : a, (or_introl (or_introl Ha b) c)) (λ H1 : b ∨ c, or_elim H1 (λ Hb : b, or_introl (or_intror a Hb) c) (λ Hc : c, or_intror (a ∨ b) Hc))) theorem or_id (a : Bool) : (a ∨ a) = a := boolext (assume H, or_elim H (λ H1, H1) (λ H2, H2)) (assume H, or_introl H a) theorem or_falsel (a : Bool) : (a ∨ false) = a := boolext (assume H, or_elim H (λ H1, H1) (λ H2, false_elim a H2)) (assume H, or_introl H false) theorem or_falser (a : Bool) : (false ∨ a) = a := (or_comm false a) ⋈ (or_falsel a) theorem or_truel (a : Bool) : (true ∨ a) = true := eqt_intro (case (λ x : Bool, true ∨ x) trivial trivial a) theorem or_truer (a : Bool) : (a ∨ true) = true := (or_comm a true) ⋈ (or_truel a) theorem or_tauto (a : Bool) : (a ∨ ¬ a) = true := eqt_intro (em a) theorem and_comm (a b : Bool) : (a ∧ b) = (b ∧ a) := boolext (assume H, and_intro (and_elimr H) (and_eliml H)) (assume H, and_intro (and_elimr H) (and_eliml H)) theorem and_id (a : Bool) : (a ∧ a) = a := boolext (assume H, and_eliml H) (assume H, and_intro H H) theorem and_assoc (a b c : Bool) : ((a ∧ b) ∧ c) = (a ∧ (b ∧ c)) := boolext (assume H, and_intro (and_eliml (and_eliml H)) (and_intro (and_elimr (and_eliml H)) (and_elimr H))) (assume H, and_intro (and_intro (and_eliml H) (and_eliml (and_elimr H))) (and_elimr (and_elimr H))) theorem and_truer (a : Bool) : (a ∧ true) = a := boolext (assume H : a ∧ true, and_eliml H) (assume H : a, and_intro H trivial) theorem and_truel (a : Bool) : (true ∧ a) = a := trans (and_comm true a) (and_truer a) theorem and_falsel (a : Bool) : (a ∧ false) = false := boolext (assume H, and_elimr H) (assume H, false_elim (a ∧ false) H) theorem and_falser (a : Bool) : (false ∧ a) = false := (and_comm false a) ⋈ (and_falsel a) theorem and_absurd (a : Bool) : (a ∧ ¬ a) = false := boolext (assume H, absurd (and_eliml H) (and_elimr H)) (assume H, false_elim (a ∧ ¬ a) H) theorem imp_truer (a : Bool) : (a → true) = true := case (λ x, (x → true) = true) trivial trivial a theorem imp_truel (a : Bool) : (true → a) = a := case (λ x, (true → x) = x) trivial trivial a theorem imp_falser (a : Bool) : (a → false) = ¬ a := refl _ theorem imp_falsel (a : Bool) : (false → a) = true := case (λ x, (false → x) = true) trivial trivial a theorem not_and (a b : Bool) : (¬ (a ∧ b)) = (¬ a ∨ ¬ b) := case (λ x, (¬ (x ∧ b)) = (¬ x ∨ ¬ b)) (case (λ y, (¬ (true ∧ y)) = (¬ true ∨ ¬ y)) trivial trivial b) (case (λ y, (¬ (false ∧ y)) = (¬ false ∨ ¬ y)) trivial trivial b) a theorem not_and_elim {a b : Bool} (H : ¬ (a ∧ b)) : ¬ a ∨ ¬ b := (not_and a b) ◂ H theorem not_or (a b : Bool) : (¬ (a ∨ b)) = (¬ a ∧ ¬ b) := case (λ x, (¬ (x ∨ b)) = (¬ x ∧ ¬ b)) (case (λ y, (¬ (true ∨ y)) = (¬ true ∧ ¬ y)) trivial trivial b) (case (λ y, (¬ (false ∨ y)) = (¬ false ∧ ¬ y)) trivial trivial b) a theorem not_or_elim {a b : Bool} (H : ¬ (a ∨ b)) : ¬ a ∧ ¬ b := (not_or a b) ◂ H theorem not_iff (a b : Bool) : (¬ (a = b)) = ((¬ a) = b) := case (λ x, (¬ (x = b)) = ((¬ x) = b)) (case (λ y, (¬ (true = y)) = ((¬ true) = y)) trivial trivial b) (case (λ y, (¬ (false = y)) = ((¬ false) = y)) trivial trivial b) a theorem not_iff_elim {a b : Bool} (H : ¬ (a = b)) : (¬ a) = b := (not_iff a b) ◂ H theorem not_implies (a b : Bool) : (¬ (a → b)) = (a ∧ ¬ b) := case (λ x, (¬ (x → b)) = (x ∧ ¬ b)) (case (λ y, (¬ (true → y)) = (true ∧ ¬ y)) trivial trivial b) (case (λ y, (¬ (false → y)) = (false ∧ ¬ y)) trivial trivial b) a theorem not_implies_elim {a b : Bool} (H : ¬ (a → b)) : a ∧ ¬ b := (not_implies a b) ◂ H theorem not_congr {a b : Bool} (H : a = b) : (¬ a) = (¬ b) := congr2 not H theorem eq_exists_intro {A : (Type U)} {P Q : A → Bool} (H : ∀ x : A, P x = Q x) : (∃ x : A, P x) = (∃ x : A, Q x) := congr2 (Exists A) (funext H) theorem not_forall (A : (Type U)) (P : A → Bool) : (¬ (∀ x : A, P x)) = (∃ x : A, ¬ P x) := calc (¬ ∀ x : A, P x) = (¬ ∀ x : A, ¬ ¬ P x) : not_congr (allext (λ x : A, symm (not_not_eq (P x)))) ... = (∃ x : A, ¬ P x) : refl (∃ x : A, ¬ P x) theorem not_forall_elim {A : (Type U)} {P : A → Bool} (H : ¬ (∀ x : A, P x)) : ∃ x : A, ¬ P x := (not_forall A P) ◂ H theorem not_exists (A : (Type U)) (P : A → Bool) : (¬ ∃ x : A, P x) = (∀ x : A, ¬ P x) := calc (¬ ∃ x : A, P x) = (¬ ¬ ∀ x : A, ¬ P x) : refl (¬ ∃ x : A, P x) ... = (∀ x : A, ¬ P x) : not_not_eq (∀ x : A, ¬ P x) theorem not_exists_elim {A : (Type U)} {P : A → Bool} (H : ¬ ∃ x : A, P x) : ∀ x : A, ¬ P x := (not_exists A P) ◂ H theorem exists_unfold1 {A : TypeU} {P : A → Bool} (a : A) (H : ∃ x : A, P x) : P a ∨ (∃ x : A, x ≠ a ∧ P x) := exists_elim H (λ (w : A) (H1 : P w), or_elim (em (w = a)) (λ Heq : w = a, or_introl (subst H1 Heq) (∃ x : A, x ≠ a ∧ P x)) (λ Hne : w ≠ a, or_intror (P a) (exists_intro w (and_intro Hne H1)))) theorem exists_unfold2 {A : TypeU} {P : A → Bool} (a : A) (H : P a ∨ (∃ x : A, x ≠ a ∧ P x)) : ∃ x : A, P x := or_elim H (λ H1 : P a, exists_intro a H1) (λ H2 : (∃ x : A, x ≠ a ∧ P x), exists_elim H2 (λ (w : A) (Hw : w ≠ a ∧ P w), exists_intro w (and_elimr Hw))) theorem exists_unfold {A : TypeU} (P : A → Bool) (a : A) : (∃ x : A, P x) = (P a ∨ (∃ x : A, x ≠ a ∧ P x)) := boolext (assume H : (∃ x : A, P x), exists_unfold1 a H) (assume H : (P a ∨ (∃ x : A, x ≠ a ∧ P x)), exists_unfold2 a H) -- Remark: ordered rewriting + assoc + comm + left_comm sorts a term lexicographically theorem left_comm {A : TypeU} {R : A -> A -> A} (comm : ∀ x y, R x y = R y x) (assoc : ∀ x y z, R (R x y) z = R x (R y z)) : ∀ x y z, R x (R y z) = R y (R x z) := take x y z, calc R x (R y z) = R (R x y) z : symm (assoc x y z) ... = R (R y x) z : { comm x y } ... = R y (R x z) : assoc y x z theorem and_left_comm (a b c : Bool) : (a ∧ (b ∧ c)) = (b ∧ (a ∧ c)) := left_comm and_comm and_assoc a b c theorem or_left_comm (a b c : Bool) : (a ∨ (b ∨ c)) = (b ∨ (a ∨ c)) := left_comm or_comm or_assoc a b c -- Congruence theorems for contextual simplification -- Simplify a → b, by first simplifying a to c using the fact that ¬ b is true, and then -- b to d using the fact that c is true theorem imp_congrr {a b c d : Bool} (H_ac : ∀ (H_nb : ¬ b), a = c) (H_bd : ∀ (H_c : c), b = d) : (a → b) = (c → d) := or_elim (em b) (λ H_b : b, or_elim (em c) (λ H_c : c, calc (a → b) = (a → true) : { eqt_intro H_b } ... = true : imp_truer a ... = (c → true) : symm (imp_truer c) ... = (c → b) : { symm (eqt_intro H_b) } ... = (c → d) : { H_bd H_c }) (λ H_nc : ¬ c, calc (a → b) = (a → true) : { eqt_intro H_b } ... = true : imp_truer a ... = (false → d) : symm (imp_falsel d) ... = (c → d) : { symm (eqf_intro H_nc) })) (λ H_nb : ¬ b, or_elim (em c) (λ H_c : c, calc (a → b) = (c → b) : { H_ac H_nb } ... = (c → d) : { H_bd H_c }) (λ H_nc : ¬ c, calc (a → b) = (c → b) : { H_ac H_nb } ... = (false → b) : { eqf_intro H_nc } ... = true : imp_falsel b ... = (false → d) : symm (imp_falsel d) ... = (c → d) : { symm (eqf_intro H_nc) })) -- Simplify a → b, by first simplifying b to d using the fact that a is true, and then -- b to d using the fact that ¬ d is true. -- This kind of congruence seems to be useful in very rare cases. theorem imp_congrl {a b c d : Bool} (H_ac : ∀ (H_nd : ¬ d), a = c) (H_bd : ∀ (H_a : a), b = d) : (a → b) = (c → d) := or_elim (em a) (λ H_a : a, or_elim (em d) (λ H_d : d, calc (a → b) = (a → d) : { H_bd H_a } ... = (a → true) : { eqt_intro H_d } ... = true : imp_truer a ... = (c → true) : symm (imp_truer c) ... = (c → d) : { symm (eqt_intro H_d) }) (λ H_nd : ¬ d, calc (a → b) = (c → b) : { H_ac H_nd } ... = (c → d) : { H_bd H_a })) (λ H_na : ¬ a, or_elim (em d) (λ H_d : d, calc (a → b) = (false → b) : { eqf_intro H_na } ... = true : imp_falsel b ... = (c → true) : symm (imp_truer c) ... = (c → d) : { symm (eqt_intro H_d) }) (λ H_nd : ¬ d, calc (a → b) = (false → b) : { eqf_intro H_na } ... = true : imp_falsel b ... = (false → d) : symm (imp_falsel d) ... = (a → d) : { symm (eqf_intro H_na) } ... = (c → d) : { H_ac H_nd })) -- (Common case) simplify a to c, and then b to d using the fact that c is true theorem imp_congr {a b c d : Bool} (H_ac : a = c) (H_bd : ∀ (H_c : c), b = d) : (a → b) = (c → d) := imp_congrr (λ H, H_ac) H_bd -- In the following theorems we are using the fact that a ∨ b is defined as ¬ a → b theorem or_congrr {a b c d : Bool} (H_ac : ∀ (H_nb : ¬ b), a = c) (H_bd : ∀ (H_nc : ¬ c), b = d) : (a ∨ b) = (c ∨ d) := imp_congrr (λ H_nb : ¬ b, congr2 not (H_ac H_nb)) H_bd theorem or_congrl {a b c d : Bool} (H_ac : ∀ (H_nd : ¬ d), a = c) (H_bd : ∀ (H_na : ¬ a), b = d) : (a ∨ b) = (c ∨ d) := imp_congrl (λ H_nd : ¬ d, congr2 not (H_ac H_nd)) H_bd -- (Common case) simplify a to c, and then b to d using the fact that ¬ c is true theorem or_congr {a b c d : Bool} (H_ac : a = c) (H_bd : ∀ (H_nc : ¬ c), b = d) : (a ∨ b) = (c ∨ d) := or_congrr (λ H, H_ac) H_bd -- In the following theorems we are using the fact hat a ∧ b is defined as ¬ (a → ¬ b) theorem and_congrr {a b c d : Bool} (H_ac : ∀ (H_b : b), a = c) (H_bd : ∀ (H_c : c), b = d) : (a ∧ b) = (c ∧ d) := congr2 not (imp_congrr (λ (H_nnb : ¬ ¬ b), H_ac (not_not_elim H_nnb)) (λ H_c : c, congr2 not (H_bd H_c))) theorem and_congrl {a b c d : Bool} (H_ac : ∀ (H_d : d), a = c) (H_bd : ∀ (H_a : a), b = d) : (a ∧ b) = (c ∧ d) := congr2 not (imp_congrl (λ (H_nnd : ¬ ¬ d), H_ac (not_not_elim H_nnd)) (λ H_a : a, congr2 not (H_bd H_a))) -- (Common case) simplify a to c, and then b to d using the fact that c is true theorem and_congr {a b c d : Bool} (H_ac : a = c) (H_bd : ∀ (H_c : c), b = d) : (a ∧ b) = (c ∧ d) := and_congrr (λ H, H_ac) H_bd theorem forall_or_distributer {A : TypeU} (p : Bool) (φ : A → Bool) : (∀ x, p ∨ φ x) = (p ∨ ∀ x, φ x) := boolext (assume H : (∀ x, p ∨ φ x), or_elim (em p) (λ Hp : p, or_introl Hp (∀ x, φ x)) (λ Hnp : ¬ p, or_intror p (take x, resolve1 (H x) Hnp))) (assume H : (p ∨ ∀ x, φ x), take x, or_elim H (λ H1 : p, or_introl H1 (φ x)) (λ H2 : (∀ x, φ x), or_intror p (H2 x))) theorem forall_or_distributel {A : TypeU} (p : Bool) (φ : A → Bool) : (∀ x, φ x ∨ p) = ((∀ x, φ x) ∨ p) := calc (∀ x, φ x ∨ p) = (∀ x, p ∨ φ x) : allext (λ x, or_comm (φ x) p) ... = (p ∨ ∀ x, φ x) : forall_or_distributer p φ ... = ((∀ x, φ x) ∨ p) : or_comm p (∀ x, φ x) theorem forall_and_distribute {A : TypeU} (φ ψ : A → Bool) : (∀ x, φ x ∧ ψ x) = ((∀ x, φ x) ∧ (∀ x, ψ x)) := boolext (assume H : (∀ x, φ x ∧ ψ x), and_intro (take x, and_eliml (H x)) (take x, and_elimr (H x))) (assume H : (∀ x, φ x) ∧ (∀ x, ψ x), take x, and_intro (and_eliml H x) (and_elimr H x)) theorem exists_and_distributer {A : TypeU} (p : Bool) (φ : A → Bool) : (∃ x, p ∧ φ x) = (p ∧ ∃ x, φ x) := boolext (assume H : (∃ x, p ∧ φ x), obtain (w : A) (Hw : p ∧ φ w), from H, and_intro (and_eliml Hw) (exists_intro w (and_elimr Hw))) (assume H : (p ∧ ∃ x, φ x), obtain (w : A) (Hw : φ w), from (and_elimr H), exists_intro w (and_intro (and_eliml H) Hw)) theorem exists_and_distributel {A : TypeU} (p : Bool) (φ : A → Bool) : (∃ x, φ x ∧ p) = ((∃ x, φ x) ∧ p) := calc (∃ x, φ x ∧ p) = (∃ x, p ∧ φ x) : eq_exists_intro (λ x, and_comm (φ x) p) ... = (p ∧ (∃ x, φ x)) : exists_and_distributer p φ ... = ((∃ x, φ x) ∧ p) : and_comm p (∃ x, φ x) theorem exists_or_distribute {A : TypeU} (φ ψ : A → Bool) : (∃ x, φ x ∨ ψ x) = ((∃ x, φ x) ∨ (∃ x, ψ x)) := boolext (assume H : (∃ x, φ x ∨ ψ x), obtain (w : A) (Hw : φ w ∨ ψ w), from H, or_elim Hw (λ Hw1 : φ w, or_introl (exists_intro w Hw1) (∃ x, ψ x)) (λ Hw2 : ψ w, or_intror (∃ x, φ x) (exists_intro w Hw2))) (assume H : (∃ x, φ x) ∨ (∃ x, ψ x), or_elim H (λ H1 : (∃ x, φ x), obtain (w : A) (Hw : φ w), from H1, exists_intro w (or_introl Hw (ψ w))) (λ H2 : (∃ x, ψ x), obtain (w : A) (Hw : ψ w), from H2, exists_intro w (or_intror (φ w) Hw))) set_opaque exists true set_opaque not true set_opaque or true set_opaque and true set_opaque implies true