/- Copyright (c) 2014 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura notation, basic datatypes and type classes -/ prelude import Init.Prelude import Init.SizeOf universe u v w def inline {α : Sort u} (a : α) : α := a @[inline] def flip {α : Sort u} {β : Sort v} {φ : Sort w} (f : α → β → φ) : β → α → φ := fun b a => f a b @[simp] theorem Function.const_apply {y : β} {x : α} : const α y x = y := rfl @[simp] theorem Function.comp_apply {f : β → δ} {g : α → β} {x : α} : comp f g x = f (g x) := rfl attribute [simp] namedPattern /-- Thunks are "lazy" values that are evaluated when first accessed using `Thunk.get/map/bind`. The value is then stored and not recomputed for all further accesses. -/ -- NOTE: the runtime has special support for the `Thunk` type to implement this behavior structure Thunk (α : Type u) : Type u where private fn : Unit → α attribute [extern "lean_mk_thunk"] Thunk.mk /-- Store a value in a thunk. Note that the value has already been computed, so there is no laziness. -/ @[extern "lean_thunk_pure"] protected def Thunk.pure (a : α) : Thunk α := ⟨fun _ => a⟩ -- NOTE: we use `Thunk.get` instead of `Thunk.fn` as the accessor primitive as the latter has an additional `Unit` argument @[extern "lean_thunk_get_own"] protected def Thunk.get (x : @& Thunk α) : α := x.fn () @[inline] protected def Thunk.map (f : α → β) (x : Thunk α) : Thunk β := ⟨fun _ => f x.get⟩ @[inline] protected def Thunk.bind (x : Thunk α) (f : α → Thunk β) : Thunk β := ⟨fun _ => (f x.get).get⟩ @[simp] theorem Thunk.sizeOf_eq [SizeOf α] (a : Thunk α) : sizeOf a = 1 + sizeOf a.get := by cases a; rfl abbrev Eq.ndrecOn.{u1, u2} {α : Sort u2} {a : α} {motive : α → Sort u1} {b : α} (h : a = b) (m : motive a) : motive b := Eq.ndrec m h structure Iff (a b : Prop) : Prop where intro :: (mp : a → b) (mpr : b → a) infix:20 " <-> " => Iff infix:20 " ↔ " => Iff inductive Sum (α : Type u) (β : Type v) where | inl (val : α) : Sum α β | inr (val : β) : Sum α β infixr:30 " ⊕ " => Sum inductive PSum (α : Sort u) (β : Sort v) where | inl (val : α) : PSum α β | inr (val : β) : PSum α β infixr:30 " ⊕' " => PSum structure Sigma {α : Type u} (β : α → Type v) where fst : α snd : β fst attribute [unbox] Sigma structure PSigma {α : Sort u} (β : α → Sort v) where fst : α snd : β fst inductive Exists {α : Sort u} (p : α → Prop) : Prop where | intro (w : α) (h : p w) : Exists p /-- Auxiliary type used to compile `for x in xs` notation. -/ inductive ForInStep (α : Type u) where | done : α → ForInStep α | yield : α → ForInStep α deriving Inhabited class ForIn (m : Type u₁ → Type u₂) (ρ : Type u) (α : outParam (Type v)) where forIn {β} [Monad m] (x : ρ) (b : β) (f : α → β → m (ForInStep β)) : m β export ForIn (forIn) class ForIn' (m : Type u₁ → Type u₂) (ρ : Type u) (α : outParam (Type v)) (d : outParam $ Membership α ρ) where forIn' {β} [Monad m] (x : ρ) (b : β) (f : (a : α) → a ∈ x → β → m (ForInStep β)) : m β export ForIn' (forIn') /-- Auxiliary type used to compile `do` notation. -/ inductive DoResultPRBC (α β σ : Type u) where | pure : α → σ → DoResultPRBC α β σ | return : β → σ → DoResultPRBC α β σ | break : σ → DoResultPRBC α β σ | continue : σ → DoResultPRBC α β σ /-- Auxiliary type used to compile `do` notation. -/ inductive DoResultPR (α β σ : Type u) where | pure : α → σ → DoResultPR α β σ | return : β → σ → DoResultPR α β σ /-- Auxiliary type used to compile `do` notation. -/ inductive DoResultBC (σ : Type u) where | break : σ → DoResultBC σ | continue : σ → DoResultBC σ /-- Auxiliary type used to compile `do` notation. -/ inductive DoResultSBC (α σ : Type u) where | pureReturn : α → σ → DoResultSBC α σ | break : σ → DoResultSBC α σ | continue : σ → DoResultSBC α σ class HasEquiv (α : Sort u) where Equiv : α → α → Sort v infix:50 " ≈ " => HasEquiv.Equiv class EmptyCollection (α : Type u) where emptyCollection : α notation "{" "}" => EmptyCollection.emptyCollection notation "∅" => EmptyCollection.emptyCollection /-- Remark: tasks have an efficient implementation in the runtime. -/ structure Task (α : Type u) : Type u where pure :: (get : α) deriving Inhabited attribute [extern "lean_task_pure"] Task.pure attribute [extern "lean_task_get_own"] Task.get namespace Task /-- Task priority. Tasks with higher priority will always be scheduled before ones with lower priority. -/ abbrev Priority := Nat def Priority.default : Priority := 0 -- see `LEAN_MAX_PRIO` def Priority.max : Priority := 8 /-- Any priority higher than `Task.Priority.max` will result in the task being scheduled immediately on a dedicated thread. This is particularly useful for long-running and/or I/O-bound tasks since Lean will by default allocate no more non-dedicated workers than the number of cores to reduce context switches. -/ def Priority.dedicated : Priority := 9 set_option linter.unusedVariables.funArgs false in @[noinline, extern "lean_task_spawn"] protected def spawn {α : Type u} (fn : Unit → α) (prio := Priority.default) : Task α := ⟨fn ()⟩ set_option linter.unusedVariables.funArgs false in @[noinline, extern "lean_task_map"] protected def map {α : Type u} {β : Type v} (f : α → β) (x : Task α) (prio := Priority.default) : Task β := ⟨f x.get⟩ set_option linter.unusedVariables.funArgs false in @[noinline, extern "lean_task_bind"] protected def bind {α : Type u} {β : Type v} (x : Task α) (f : α → Task β) (prio := Priority.default) : Task β := ⟨(f x.get).get⟩ end Task /-- Some type that is not a scalar value in our runtime. -/ structure NonScalar where val : Nat /-- Some type that is not a scalar value in our runtime and is universe polymorphic. -/ inductive PNonScalar : Type u where | mk (v : Nat) : PNonScalar @[simp] theorem Nat.add_zero (n : Nat) : n + 0 = n := rfl theorem optParam_eq (α : Sort u) (default : α) : optParam α default = α := rfl /-! # Boolean operators -/ @[extern c inline "#1 || #2"] def strictOr (b₁ b₂ : Bool) := b₁ || b₂ @[extern c inline "#1 && #2"] def strictAnd (b₁ b₂ : Bool) := b₁ && b₂ @[inline] def bne {α : Type u} [BEq α] (a b : α) : Bool := !(a == b) infix:50 " != " => bne class LawfulBEq (α : Type u) [BEq α] : Prop where eq_of_beq : {a b : α} → (a == b) = true → a = b protected rfl : {a : α} → (a == a) = true export LawfulBEq (eq_of_beq) instance : LawfulBEq Bool where eq_of_beq {a b} h := by cases a <;> cases b <;> first | rfl | contradiction rfl {a} := by cases a <;> decide instance [DecidableEq α] : LawfulBEq α where eq_of_beq := of_decide_eq_true rfl := of_decide_eq_self_eq_true _ instance : LawfulBEq Char := inferInstance instance : LawfulBEq String := inferInstance /-! # Logical connectives and equality -/ def implies (a b : Prop) := a → b theorem implies.trans {p q r : Prop} (h₁ : implies p q) (h₂ : implies q r) : implies p r := fun hp => h₂ (h₁ hp) def trivial : True := ⟨⟩ theorem mt {a b : Prop} (h₁ : a → b) (h₂ : ¬b) : ¬a := fun ha => h₂ (h₁ ha) theorem not_false : ¬False := id theorem not_not_intro {p : Prop} (h : p) : ¬ ¬ p := fun hn : ¬ p => hn h -- proof irrelevance is built in theorem proofIrrel {a : Prop} (h₁ h₂ : a) : h₁ = h₂ := rfl theorem id.def {α : Sort u} (a : α) : id a = a := rfl @[macroInline] def Eq.mp {α β : Sort u} (h : α = β) (a : α) : β := h ▸ a @[macroInline] def Eq.mpr {α β : Sort u} (h : α = β) (b : β) : α := h ▸ b theorem Eq.substr {α : Sort u} {p : α → Prop} {a b : α} (h₁ : b = a) (h₂ : p a) : p b := h₁ ▸ h₂ theorem cast_eq {α : Sort u} (h : α = α) (a : α) : cast h a = a := rfl @[reducible] def Ne {α : Sort u} (a b : α) := ¬(a = b) infix:50 " ≠ " => Ne section Ne variable {α : Sort u} variable {a b : α} {p : Prop} theorem Ne.intro (h : a = b → False) : a ≠ b := h theorem Ne.elim (h : a ≠ b) : a = b → False := h theorem Ne.irrefl (h : a ≠ a) : False := h rfl theorem Ne.symm (h : a ≠ b) : b ≠ a := fun h₁ => h (h₁.symm) theorem false_of_ne : a ≠ a → False := Ne.irrefl theorem ne_false_of_self : p → p ≠ False := fun (hp : p) (h : p = False) => h ▸ hp theorem ne_true_of_not : ¬p → p ≠ True := fun (hnp : ¬p) (h : p = True) => have : ¬True := h ▸ hnp this trivial theorem true_ne_false : ¬True = False := ne_false_of_self trivial end Ne theorem Bool.of_not_eq_true : {b : Bool} → ¬ (b = true) → b = false | true, h => absurd rfl h | false, _ => rfl theorem Bool.of_not_eq_false : {b : Bool} → ¬ (b = false) → b = true | true, _ => rfl | false, h => absurd rfl h theorem ne_of_beq_false [BEq α] [LawfulBEq α] {a b : α} (h : (a == b) = false) : a ≠ b := by intro h'; subst h'; have : true = false := Eq.trans LawfulBEq.rfl.symm h; contradiction theorem beq_false_of_ne [BEq α] [LawfulBEq α] {a b : α} (h : a ≠ b) : (a == b) = false := have : ¬ (a == b) = true := by intro h'; rw [eq_of_beq h'] at h; contradiction Bool.of_not_eq_true this section variable {α β φ : Sort u} {a a' : α} {b b' : β} {c : φ} theorem HEq.ndrec.{u1, u2} {α : Sort u2} {a : α} {motive : {β : Sort u2} → β → Sort u1} (m : motive a) {β : Sort u2} {b : β} (h : HEq a b) : motive b := h.rec m theorem HEq.ndrecOn.{u1, u2} {α : Sort u2} {a : α} {motive : {β : Sort u2} → β → Sort u1} {β : Sort u2} {b : β} (h : HEq a b) (m : motive a) : motive b := h.rec m theorem HEq.elim {α : Sort u} {a : α} {p : α → Sort v} {b : α} (h₁ : HEq a b) (h₂ : p a) : p b := eq_of_heq h₁ ▸ h₂ theorem HEq.subst {p : (T : Sort u) → T → Prop} (h₁ : HEq a b) (h₂ : p α a) : p β b := HEq.ndrecOn h₁ h₂ theorem HEq.symm (h : HEq a b) : HEq b a := h.rec (HEq.refl a) theorem heq_of_eq (h : a = a') : HEq a a' := Eq.subst h (HEq.refl a) theorem HEq.trans (h₁ : HEq a b) (h₂ : HEq b c) : HEq a c := HEq.subst h₂ h₁ theorem heq_of_heq_of_eq (h₁ : HEq a b) (h₂ : b = b') : HEq a b' := HEq.trans h₁ (heq_of_eq h₂) theorem heq_of_eq_of_heq (h₁ : a = a') (h₂ : HEq a' b) : HEq a b := HEq.trans (heq_of_eq h₁) h₂ def type_eq_of_heq (h : HEq a b) : α = β := h.rec (Eq.refl α) end theorem eqRec_heq {α : Sort u} {φ : α → Sort v} {a a' : α} : (h : a = a') → (p : φ a) → HEq (Eq.recOn (motive := fun x _ => φ x) h p) p | rfl, p => HEq.refl p theorem heq_of_eqRec_eq {α β : Sort u} {a : α} {b : β} (h₁ : α = β) (h₂ : Eq.rec (motive := fun α _ => α) a h₁ = b) : HEq a b := by subst h₁ apply heq_of_eq exact h₂ theorem cast_heq {α β : Sort u} : (h : α = β) → (a : α) → HEq (cast h a) a | rfl, a => HEq.refl a variable {a b c d : Prop} theorem iff_iff_implies_and_implies (a b : Prop) : (a ↔ b) ↔ (a → b) ∧ (b → a) := Iff.intro (fun h => And.intro h.mp h.mpr) (fun h => Iff.intro h.left h.right) theorem Iff.refl (a : Prop) : a ↔ a := Iff.intro (fun h => h) (fun h => h) protected theorem Iff.rfl {a : Prop} : a ↔ a := Iff.refl a theorem Iff.trans (h₁ : a ↔ b) (h₂ : b ↔ c) : a ↔ c := Iff.intro (fun ha => Iff.mp h₂ (Iff.mp h₁ ha)) (fun hc => Iff.mpr h₁ (Iff.mpr h₂ hc)) theorem Iff.symm (h : a ↔ b) : b ↔ a := Iff.intro (Iff.mpr h) (Iff.mp h) theorem Iff.comm : (a ↔ b) ↔ (b ↔ a) := Iff.intro Iff.symm Iff.symm theorem And.comm : a ∧ b ↔ b ∧ a := by constructor <;> intro ⟨h₁, h₂⟩ <;> exact ⟨h₂, h₁⟩ /-! # Exists -/ theorem Exists.elim {α : Sort u} {p : α → Prop} {b : Prop} (h₁ : Exists (fun x => p x)) (h₂ : ∀ (a : α), p a → b) : b := match h₁ with | intro a h => h₂ a h /-! # Decidable -/ theorem decide_true_eq_true (h : Decidable True) : @decide True h = true := match h with | isTrue _ => rfl | isFalse h => False.elim <| h ⟨⟩ theorem decide_false_eq_false (h : Decidable False) : @decide False h = false := match h with | isFalse _ => rfl | isTrue h => False.elim h /-- Similar to `decide`, but uses an explicit instance -/ @[inline] def toBoolUsing {p : Prop} (d : Decidable p) : Bool := decide p (h := d) theorem toBoolUsing_eq_true {p : Prop} (d : Decidable p) (h : p) : toBoolUsing d = true := decide_eq_true (inst := d) h theorem ofBoolUsing_eq_true {p : Prop} {d : Decidable p} (h : toBoolUsing d = true) : p := of_decide_eq_true (inst := d) h theorem ofBoolUsing_eq_false {p : Prop} {d : Decidable p} (h : toBoolUsing d = false) : ¬ p := of_decide_eq_false (inst := d) h instance : Decidable True := isTrue trivial instance : Decidable False := isFalse not_false namespace Decidable variable {p q : Prop} @[macroInline] def byCases {q : Sort u} [dec : Decidable p] (h1 : p → q) (h2 : ¬p → q) : q := match dec with | isTrue h => h1 h | isFalse h => h2 h theorem em (p : Prop) [Decidable p] : p ∨ ¬p := byCases Or.inl Or.inr set_option linter.unusedVariables.funArgs false in theorem byContradiction [dec : Decidable p] (h : ¬p → False) : p := byCases id (fun np => False.elim (h np)) theorem of_not_not [Decidable p] : ¬ ¬ p → p := fun hnn => byContradiction (fun hn => absurd hn hnn) theorem not_and_iff_or_not (p q : Prop) [d₁ : Decidable p] [d₂ : Decidable q] : ¬ (p ∧ q) ↔ ¬ p ∨ ¬ q := Iff.intro (fun h => match d₁, d₂ with | isTrue h₁, isTrue h₂ => absurd (And.intro h₁ h₂) h | _, isFalse h₂ => Or.inr h₂ | isFalse h₁, _ => Or.inl h₁) (fun (h) ⟨hp, hq⟩ => match h with | Or.inl h => h hp | Or.inr h => h hq) end Decidable section variable {p q : Prop} @[inline] def decidable_of_decidable_of_iff [Decidable p] (h : p ↔ q) : Decidable q := if hp : p then isTrue (Iff.mp h hp) else isFalse fun hq => absurd (Iff.mpr h hq) hp @[inline] def decidable_of_decidable_of_eq [hp : Decidable p] (h : p = q) : Decidable q := h ▸ hp end @[macroInline] instance {p q} [Decidable p] [Decidable q] : Decidable (p → q) := if hp : p then if hq : q then isTrue (fun _ => hq) else isFalse (fun h => absurd (h hp) hq) else isTrue (fun h => absurd h hp) instance {p q} [Decidable p] [Decidable q] : Decidable (p ↔ q) := if hp : p then if hq : q then isTrue ⟨fun _ => hq, fun _ => hp⟩ else isFalse fun h => hq (h.1 hp) else if hq : q then isFalse fun h => hp (h.2 hq) else isTrue ⟨fun h => absurd h hp, fun h => absurd h hq⟩ /-! # if-then-else expression theorems -/ theorem if_pos {c : Prop} {h : Decidable c} (hc : c) {α : Sort u} {t e : α} : (ite c t e) = t := match h with | isTrue _ => rfl | isFalse hnc => absurd hc hnc theorem if_neg {c : Prop} {h : Decidable c} (hnc : ¬c) {α : Sort u} {t e : α} : (ite c t e) = e := match h with | isTrue hc => absurd hc hnc | isFalse _ => rfl theorem dif_pos {c : Prop} {h : Decidable c} (hc : c) {α : Sort u} {t : c → α} {e : ¬ c → α} : (dite c t e) = t hc := match h with | isTrue _ => rfl | isFalse hnc => absurd hc hnc theorem dif_neg {c : Prop} {h : Decidable c} (hnc : ¬c) {α : Sort u} {t : c → α} {e : ¬ c → α} : (dite c t e) = e hnc := match h with | isTrue hc => absurd hc hnc | isFalse _ => rfl -- Remark: dite and ite are "defally equal" when we ignore the proofs. theorem dif_eq_if (c : Prop) {h : Decidable c} {α : Sort u} (t : α) (e : α) : dite c (fun _ => t) (fun _ => e) = ite c t e := match h with | isTrue _ => rfl | isFalse _ => rfl instance {c t e : Prop} [dC : Decidable c] [dT : Decidable t] [dE : Decidable e] : Decidable (if c then t else e) := match dC with | isTrue _ => dT | isFalse _ => dE instance {c : Prop} {t : c → Prop} {e : ¬c → Prop} [dC : Decidable c] [dT : ∀ h, Decidable (t h)] [dE : ∀ h, Decidable (e h)] : Decidable (if h : c then t h else e h) := match dC with | isTrue hc => dT hc | isFalse hc => dE hc /-- Auxiliary definitions for generating compact `noConfusion` for enumeration types -/ abbrev noConfusionTypeEnum {α : Sort u} {β : Sort v} [inst : DecidableEq β] (f : α → β) (P : Sort w) (x y : α) : Sort w := (inst (f x) (f y)).casesOn (fun _ => P) (fun _ => P → P) abbrev noConfusionEnum {α : Sort u} {β : Sort v} [inst : DecidableEq β] (f : α → β) {P : Sort w} {x y : α} (h : x = y) : noConfusionTypeEnum f P x y := Decidable.casesOn (motive := fun (inst : Decidable (f x = f y)) => Decidable.casesOn (motive := fun _ => Sort w) inst (fun _ => P) (fun _ => P → P)) (inst (f x) (f y)) (fun h' => False.elim (h' (congrArg f h))) (fun _ => fun x => x) /-! # Inhabited -/ instance : Inhabited Prop where default := True deriving instance Inhabited for NonScalar, PNonScalar, True, ForInStep theorem nonempty_of_exists {α : Sort u} {p : α → Prop} : Exists (fun x => p x) → Nonempty α | ⟨w, _⟩ => ⟨w⟩ /-! # Subsingleton -/ class Subsingleton (α : Sort u) : Prop where intro :: allEq : (a b : α) → a = b protected def Subsingleton.elim {α : Sort u} [h : Subsingleton α] : (a b : α) → a = b := h.allEq protected def Subsingleton.helim {α β : Sort u} [h₁ : Subsingleton α] (h₂ : α = β) (a : α) (b : β) : HEq a b := by subst h₂ apply heq_of_eq apply Subsingleton.elim instance (p : Prop) : Subsingleton p := ⟨fun a b => proofIrrel a b⟩ instance (p : Prop) : Subsingleton (Decidable p) := Subsingleton.intro fun | isTrue t₁ => fun | isTrue _ => rfl | isFalse f₂ => absurd t₁ f₂ | isFalse f₁ => fun | isTrue t₂ => absurd t₂ f₁ | isFalse _ => rfl theorem recSubsingleton {p : Prop} [h : Decidable p] {h₁ : p → Sort u} {h₂ : ¬p → Sort u} [h₃ : ∀ (h : p), Subsingleton (h₁ h)] [h₄ : ∀ (h : ¬p), Subsingleton (h₂ h)] : Subsingleton (h.casesOn h₂ h₁) := match h with | isTrue h => h₃ h | isFalse h => h₄ h structure Equivalence {α : Sort u} (r : α → α → Prop) : Prop where refl : ∀ x, r x x symm : ∀ {x y}, r x y → r y x trans : ∀ {x y z}, r x y → r y z → r x z def emptyRelation {α : Sort u} (_ _ : α) : Prop := False def Subrelation {α : Sort u} (q r : α → α → Prop) := ∀ {x y}, q x y → r x y def InvImage {α : Sort u} {β : Sort v} (r : β → β → Prop) (f : α → β) : α → α → Prop := fun a₁ a₂ => r (f a₁) (f a₂) inductive TC {α : Sort u} (r : α → α → Prop) : α → α → Prop where | base : ∀ a b, r a b → TC r a b | trans : ∀ a b c, TC r a b → TC r b c → TC r a c /-! # Subtype -/ namespace Subtype def existsOfSubtype {α : Type u} {p : α → Prop} : { x // p x } → Exists (fun x => p x) | ⟨a, h⟩ => ⟨a, h⟩ variable {α : Type u} {p : α → Prop} protected theorem eq : ∀ {a1 a2 : {x // p x}}, val a1 = val a2 → a1 = a2 | ⟨_, _⟩, ⟨_, _⟩, rfl => rfl theorem eta (a : {x // p x}) (h : p (val a)) : mk (val a) h = a := by cases a exact rfl instance {α : Type u} {p : α → Prop} {a : α} (h : p a) : Inhabited {x // p x} where default := ⟨a, h⟩ instance {α : Type u} {p : α → Prop} [DecidableEq α] : DecidableEq {x : α // p x} := fun ⟨a, h₁⟩ ⟨b, h₂⟩ => if h : a = b then isTrue (by subst h; exact rfl) else isFalse (fun h' => Subtype.noConfusion h' (fun h' => absurd h' h)) end Subtype /-! # Sum -/ section variable {α : Type u} {β : Type v} instance Sum.inhabitedLeft [Inhabited α] : Inhabited (Sum α β) where default := Sum.inl default instance Sum.inhabitedRight [Inhabited β] : Inhabited (Sum α β) where default := Sum.inr default instance {α : Type u} {β : Type v} [DecidableEq α] [DecidableEq β] : DecidableEq (Sum α β) := fun a b => match a, b with | Sum.inl a, Sum.inl b => if h : a = b then isTrue (h ▸ rfl) else isFalse fun h' => Sum.noConfusion h' fun h' => absurd h' h | Sum.inr a, Sum.inr b => if h : a = b then isTrue (h ▸ rfl) else isFalse fun h' => Sum.noConfusion h' fun h' => absurd h' h | Sum.inr _, Sum.inl _ => isFalse fun h => Sum.noConfusion h | Sum.inl _, Sum.inr _ => isFalse fun h => Sum.noConfusion h end /-! # Product -/ instance [Inhabited α] [Inhabited β] : Inhabited (α × β) where default := (default, default) instance [Inhabited α] [Inhabited β] : Inhabited (MProd α β) where default := ⟨default, default⟩ instance [Inhabited α] [Inhabited β] : Inhabited (PProd α β) where default := ⟨default, default⟩ instance [DecidableEq α] [DecidableEq β] : DecidableEq (α × β) := fun (a, b) (a', b') => match decEq a a' with | isTrue e₁ => match decEq b b' with | isTrue e₂ => isTrue (e₁ ▸ e₂ ▸ rfl) | isFalse n₂ => isFalse fun h => Prod.noConfusion h fun _ e₂' => absurd e₂' n₂ | isFalse n₁ => isFalse fun h => Prod.noConfusion h fun e₁' _ => absurd e₁' n₁ instance [BEq α] [BEq β] : BEq (α × β) where beq := fun (a₁, b₁) (a₂, b₂) => a₁ == a₂ && b₁ == b₂ instance [LT α] [LT β] : LT (α × β) where lt s t := s.1 < t.1 ∨ (s.1 = t.1 ∧ s.2 < t.2) instance prodHasDecidableLt [LT α] [LT β] [DecidableEq α] [DecidableEq β] [(a b : α) → Decidable (a < b)] [(a b : β) → Decidable (a < b)] : (s t : α × β) → Decidable (s < t) := fun _ _ => inferInstanceAs (Decidable (_ ∨ _)) theorem Prod.lt_def [LT α] [LT β] (s t : α × β) : (s < t) = (s.1 < t.1 ∨ (s.1 = t.1 ∧ s.2 < t.2)) := rfl theorem Prod.ext (p : α × β) : (p.1, p.2) = p := by cases p; rfl def Prod.map {α₁ : Type u₁} {α₂ : Type u₂} {β₁ : Type v₁} {β₂ : Type v₂} (f : α₁ → α₂) (g : β₁ → β₂) : α₁ × β₁ → α₂ × β₂ | (a, b) => (f a, g b) /-! # Dependent products -/ theorem ex_of_PSigma {α : Type u} {p : α → Prop} : (PSigma (fun x => p x)) → Exists (fun x => p x) | ⟨x, hx⟩ => ⟨x, hx⟩ protected theorem PSigma.eta {α : Sort u} {β : α → Sort v} {a₁ a₂ : α} {b₁ : β a₁} {b₂ : β a₂} (h₁ : a₁ = a₂) (h₂ : Eq.ndrec b₁ h₁ = b₂) : PSigma.mk a₁ b₁ = PSigma.mk a₂ b₂ := by subst h₁ subst h₂ exact rfl /-! # Universe polymorphic unit -/ theorem PUnit.subsingleton (a b : PUnit) : a = b := by cases a; cases b; exact rfl theorem PUnit.eq_punit (a : PUnit) : a = ⟨⟩ := PUnit.subsingleton a ⟨⟩ instance : Subsingleton PUnit := Subsingleton.intro PUnit.subsingleton instance : Inhabited PUnit where default := ⟨⟩ instance : DecidableEq PUnit := fun a b => isTrue (PUnit.subsingleton a b) /-! # Setoid -/ class Setoid (α : Sort u) where r : α → α → Prop iseqv : Equivalence r instance {α : Sort u} [Setoid α] : HasEquiv α := ⟨Setoid.r⟩ namespace Setoid variable {α : Sort u} [Setoid α] theorem refl (a : α) : a ≈ a := iseqv.refl a theorem symm {a b : α} (hab : a ≈ b) : b ≈ a := iseqv.symm hab theorem trans {a b c : α} (hab : a ≈ b) (hbc : b ≈ c) : a ≈ c := iseqv.trans hab hbc end Setoid /-! # Propositional extensionality -/ axiom propext {a b : Prop} : (a ↔ b) → a = b theorem Eq.propIntro {a b : Prop} (h₁ : a → b) (h₂ : b → a) : a = b := propext <| Iff.intro h₁ h₂ -- Eq for Prop is now decidable if the equivalent Iff is decidable instance {p q : Prop} [d : Decidable (p ↔ q)] : Decidable (p = q) := match d with | isTrue h => isTrue (propext h) | isFalse h => isFalse fun heq => h (heq ▸ Iff.rfl) gen_injective_theorems% Prod gen_injective_theorems% PProd gen_injective_theorems% MProd gen_injective_theorems% Subtype gen_injective_theorems% Fin gen_injective_theorems% Array gen_injective_theorems% Sum gen_injective_theorems% PSum gen_injective_theorems% Nat gen_injective_theorems% Option gen_injective_theorems% List gen_injective_theorems% Except gen_injective_theorems% EStateM.Result gen_injective_theorems% Lean.Name gen_injective_theorems% Lean.Syntax @[simp] theorem beq_iff_eq [BEq α] [LawfulBEq α] (a b : α) : a == b ↔ a = b := ⟨eq_of_beq, by intro h; subst h; exact LawfulBEq.rfl⟩ /-! # Quotients -/ /-- Iff can now be used to do substitutions in a calculation -/ theorem Iff.subst {a b : Prop} {p : Prop → Prop} (h₁ : a ↔ b) (h₂ : p a) : p b := Eq.subst (propext h₁) h₂ namespace Quot axiom sound : ∀ {α : Sort u} {r : α → α → Prop} {a b : α}, r a b → Quot.mk r a = Quot.mk r b protected theorem liftBeta {α : Sort u} {r : α → α → Prop} {β : Sort v} (f : α → β) (c : (a b : α) → r a b → f a = f b) (a : α) : lift f c (Quot.mk r a) = f a := rfl protected theorem indBeta {α : Sort u} {r : α → α → Prop} {motive : Quot r → Prop} (p : (a : α) → motive (Quot.mk r a)) (a : α) : (ind p (Quot.mk r a) : motive (Quot.mk r a)) = p a := rfl protected abbrev liftOn {α : Sort u} {β : Sort v} {r : α → α → Prop} (q : Quot r) (f : α → β) (c : (a b : α) → r a b → f a = f b) : β := lift f c q @[elabAsElim] protected theorem inductionOn {α : Sort u} {r : α → α → Prop} {motive : Quot r → Prop} (q : Quot r) (h : (a : α) → motive (Quot.mk r a)) : motive q := ind h q theorem exists_rep {α : Sort u} {r : α → α → Prop} (q : Quot r) : Exists (fun a => (Quot.mk r a) = q) := q.inductionOn (fun a => ⟨a, rfl⟩) section variable {α : Sort u} variable {r : α → α → Prop} variable {motive : Quot r → Sort v} @[reducible, macroInline] protected def indep (f : (a : α) → motive (Quot.mk r a)) (a : α) : PSigma motive := ⟨Quot.mk r a, f a⟩ protected theorem indepCoherent (f : (a : α) → motive (Quot.mk r a)) (h : (a b : α) → (p : r a b) → Eq.ndrec (f a) (sound p) = f b) : (a b : α) → r a b → Quot.indep f a = Quot.indep f b := fun a b e => PSigma.eta (sound e) (h a b e) protected theorem liftIndepPr1 (f : (a : α) → motive (Quot.mk r a)) (h : ∀ (a b : α) (p : r a b), Eq.ndrec (f a) (sound p) = f b) (q : Quot r) : (lift (Quot.indep f) (Quot.indepCoherent f h) q).1 = q := by induction q using Quot.ind exact rfl protected abbrev rec (f : (a : α) → motive (Quot.mk r a)) (h : (a b : α) → (p : r a b) → Eq.ndrec (f a) (sound p) = f b) (q : Quot r) : motive q := Eq.ndrecOn (Quot.liftIndepPr1 f h q) ((lift (Quot.indep f) (Quot.indepCoherent f h) q).2) protected abbrev recOn (q : Quot r) (f : (a : α) → motive (Quot.mk r a)) (h : (a b : α) → (p : r a b) → Eq.ndrec (f a) (sound p) = f b) : motive q := q.rec f h protected abbrev recOnSubsingleton [h : (a : α) → Subsingleton (motive (Quot.mk r a))] (q : Quot r) (f : (a : α) → motive (Quot.mk r a)) : motive q := by induction q using Quot.rec apply f apply Subsingleton.elim protected abbrev hrecOn (q : Quot r) (f : (a : α) → motive (Quot.mk r a)) (c : (a b : α) → (p : r a b) → HEq (f a) (f b)) : motive q := Quot.recOn q f fun a b p => eq_of_heq <| have p₁ : HEq (Eq.ndrec (f a) (sound p)) (f a) := eqRec_heq (sound p) (f a) HEq.trans p₁ (c a b p) end end Quot set_option linter.unusedVariables.funArgs false in def Quotient {α : Sort u} (s : Setoid α) := @Quot α Setoid.r namespace Quotient @[inline] protected def mk {α : Sort u} (s : Setoid α) (a : α) : Quotient s := Quot.mk Setoid.r a protected def mk' {α : Sort u} [s : Setoid α] (a : α) : Quotient s := Quotient.mk s a def sound {α : Sort u} {s : Setoid α} {a b : α} : a ≈ b → Quotient.mk s a = Quotient.mk s b := Quot.sound protected abbrev lift {α : Sort u} {β : Sort v} {s : Setoid α} (f : α → β) : ((a b : α) → a ≈ b → f a = f b) → Quotient s → β := Quot.lift f protected theorem ind {α : Sort u} {s : Setoid α} {motive : Quotient s → Prop} : ((a : α) → motive (Quotient.mk s a)) → (q : Quot Setoid.r) → motive q := Quot.ind protected abbrev liftOn {α : Sort u} {β : Sort v} {s : Setoid α} (q : Quotient s) (f : α → β) (c : (a b : α) → a ≈ b → f a = f b) : β := Quot.liftOn q f c @[elabAsElim] protected theorem inductionOn {α : Sort u} {s : Setoid α} {motive : Quotient s → Prop} (q : Quotient s) (h : (a : α) → motive (Quotient.mk s a)) : motive q := Quot.inductionOn q h theorem exists_rep {α : Sort u} {s : Setoid α} (q : Quotient s) : Exists (fun (a : α) => Quotient.mk s a = q) := Quot.exists_rep q section variable {α : Sort u} variable {s : Setoid α} variable {motive : Quotient s → Sort v} @[inline, elabAsElim] protected def rec (f : (a : α) → motive (Quotient.mk s a)) (h : (a b : α) → (p : a ≈ b) → Eq.ndrec (f a) (Quotient.sound p) = f b) (q : Quotient s) : motive q := Quot.rec f h q @[elabAsElim] protected abbrev recOn (q : Quotient s) (f : (a : α) → motive (Quotient.mk s a)) (h : (a b : α) → (p : a ≈ b) → Eq.ndrec (f a) (Quotient.sound p) = f b) : motive q := Quot.recOn q f h @[elabAsElim] protected abbrev recOnSubsingleton [h : (a : α) → Subsingleton (motive (Quotient.mk s a))] (q : Quotient s) (f : (a : α) → motive (Quotient.mk s a)) : motive q := Quot.recOnSubsingleton (h := h) q f @[elabAsElim] protected abbrev hrecOn (q : Quotient s) (f : (a : α) → motive (Quotient.mk s a)) (c : (a b : α) → (p : a ≈ b) → HEq (f a) (f b)) : motive q := Quot.hrecOn q f c end section universe uA uB uC variable {α : Sort uA} {β : Sort uB} {φ : Sort uC} variable {s₁ : Setoid α} {s₂ : Setoid β} protected abbrev lift₂ (f : α → β → φ) (c : (a₁ : α) → (b₁ : β) → (a₂ : α) → (b₂ : β) → a₁ ≈ a₂ → b₁ ≈ b₂ → f a₁ b₁ = f a₂ b₂) (q₁ : Quotient s₁) (q₂ : Quotient s₂) : φ := by apply Quotient.lift (fun (a₁ : α) => Quotient.lift (f a₁) (fun (a b : β) => c a₁ a a₁ b (Setoid.refl a₁)) q₂) _ q₁ intros induction q₂ using Quotient.ind apply c; assumption; apply Setoid.refl protected abbrev liftOn₂ (q₁ : Quotient s₁) (q₂ : Quotient s₂) (f : α → β → φ) (c : (a₁ : α) → (b₁ : β) → (a₂ : α) → (b₂ : β) → a₁ ≈ a₂ → b₁ ≈ b₂ → f a₁ b₁ = f a₂ b₂) : φ := Quotient.lift₂ f c q₁ q₂ @[elabAsElim] protected theorem ind₂ {motive : Quotient s₁ → Quotient s₂ → Prop} (h : (a : α) → (b : β) → motive (Quotient.mk s₁ a) (Quotient.mk s₂ b)) (q₁ : Quotient s₁) (q₂ : Quotient s₂) : motive q₁ q₂ := by induction q₁ using Quotient.ind induction q₂ using Quotient.ind apply h @[elabAsElim] protected theorem inductionOn₂ {motive : Quotient s₁ → Quotient s₂ → Prop} (q₁ : Quotient s₁) (q₂ : Quotient s₂) (h : (a : α) → (b : β) → motive (Quotient.mk s₁ a) (Quotient.mk s₂ b)) : motive q₁ q₂ := by induction q₁ using Quotient.ind induction q₂ using Quotient.ind apply h @[elabAsElim] protected theorem inductionOn₃ {s₃ : Setoid φ} {motive : Quotient s₁ → Quotient s₂ → Quotient s₃ → Prop} (q₁ : Quotient s₁) (q₂ : Quotient s₂) (q₃ : Quotient s₃) (h : (a : α) → (b : β) → (c : φ) → motive (Quotient.mk s₁ a) (Quotient.mk s₂ b) (Quotient.mk s₃ c)) : motive q₁ q₂ q₃ := by induction q₁ using Quotient.ind induction q₂ using Quotient.ind induction q₃ using Quotient.ind apply h end section Exact variable {α : Sort u} private def rel {s : Setoid α} (q₁ q₂ : Quotient s) : Prop := Quotient.liftOn₂ q₁ q₂ (fun a₁ a₂ => a₁ ≈ a₂) (fun _ _ _ _ a₁b₁ a₂b₂ => propext (Iff.intro (fun a₁a₂ => Setoid.trans (Setoid.symm a₁b₁) (Setoid.trans a₁a₂ a₂b₂)) (fun b₁b₂ => Setoid.trans a₁b₁ (Setoid.trans b₁b₂ (Setoid.symm a₂b₂))))) private theorem rel.refl {s : Setoid α} (q : Quotient s) : rel q q := q.inductionOn Setoid.refl private theorem rel_of_eq {s : Setoid α} {q₁ q₂ : Quotient s} : q₁ = q₂ → rel q₁ q₂ := fun h => Eq.ndrecOn h (rel.refl q₁) theorem exact {s : Setoid α} {a b : α} : Quotient.mk s a = Quotient.mk s b → a ≈ b := fun h => rel_of_eq h end Exact section universe uA uB uC variable {α : Sort uA} {β : Sort uB} variable {s₁ : Setoid α} {s₂ : Setoid β} @[elabAsElim] protected abbrev recOnSubsingleton₂ {motive : Quotient s₁ → Quotient s₂ → Sort uC} [s : (a : α) → (b : β) → Subsingleton (motive (Quotient.mk s₁ a) (Quotient.mk s₂ b))] (q₁ : Quotient s₁) (q₂ : Quotient s₂) (g : (a : α) → (b : β) → motive (Quotient.mk s₁ a) (Quotient.mk s₂ b)) : motive q₁ q₂ := by induction q₁ using Quot.recOnSubsingleton induction q₂ using Quot.recOnSubsingleton apply g intro a; apply s induction q₂ using Quot.recOnSubsingleton intro a; apply s infer_instance end end Quotient section variable {α : Type u} variable (r : α → α → Prop) instance {α : Sort u} {s : Setoid α} [d : ∀ (a b : α), Decidable (a ≈ b)] : DecidableEq (Quotient s) := fun (q₁ q₂ : Quotient s) => Quotient.recOnSubsingleton₂ q₁ q₂ fun a₁ a₂ => match d a₁ a₂ with | isTrue h₁ => isTrue (Quotient.sound h₁) | isFalse h₂ => isFalse fun h => absurd (Quotient.exact h) h₂ /-! # Function extensionality -/ namespace Function variable {α : Sort u} {β : α → Sort v} protected def Equiv (f₁ f₂ : ∀ (x : α), β x) : Prop := ∀ x, f₁ x = f₂ x protected theorem Equiv.refl (f : ∀ (x : α), β x) : Function.Equiv f f := fun _ => rfl protected theorem Equiv.symm {f₁ f₂ : ∀ (x : α), β x} : Function.Equiv f₁ f₂ → Function.Equiv f₂ f₁ := fun h x => Eq.symm (h x) protected theorem Equiv.trans {f₁ f₂ f₃ : ∀ (x : α), β x} : Function.Equiv f₁ f₂ → Function.Equiv f₂ f₃ → Function.Equiv f₁ f₃ := fun h₁ h₂ x => Eq.trans (h₁ x) (h₂ x) protected theorem Equiv.isEquivalence (α : Sort u) (β : α → Sort v) : Equivalence (@Function.Equiv α β) := { refl := Equiv.refl symm := Equiv.symm trans := Equiv.trans } end Function section open Quotient variable {α : Sort u} {β : α → Sort v} @[instance] private def funSetoid (α : Sort u) (β : α → Sort v) : Setoid (∀ (x : α), β x) := Setoid.mk (@Function.Equiv α β) (Function.Equiv.isEquivalence α β) private def extfunApp (f : Quotient <| funSetoid α β) (x : α) : β x := Quot.liftOn f (fun (f : ∀ (x : α), β x) => f x) (fun _ _ h => h x) theorem funext {f₁ f₂ : ∀ (x : α), β x} (h : ∀ x, f₁ x = f₂ x) : f₁ = f₂ := by show extfunApp (Quotient.mk' f₁) = extfunApp (Quotient.mk' f₂) apply congrArg apply Quotient.sound exact h end instance {α : Sort u} {β : α → Sort v} [∀ a, Subsingleton (β a)] : Subsingleton (∀ a, β a) where allEq f₁ f₂ := funext (fun a => Subsingleton.elim (f₁ a) (f₂ a)) /-! # Squash -/ def Squash (α : Type u) := Quot (fun (_ _ : α) => True) def Squash.mk {α : Type u} (x : α) : Squash α := Quot.mk _ x theorem Squash.ind {α : Type u} {motive : Squash α → Prop} (h : ∀ (a : α), motive (Squash.mk a)) : ∀ (q : Squash α), motive q := Quot.ind h @[inline] def Squash.lift {α β} [Subsingleton β] (s : Squash α) (f : α → β) : β := Quot.lift f (fun _ _ _ => Subsingleton.elim _ _) s instance : Subsingleton (Squash α) where allEq a b := by induction a using Squash.ind induction b using Squash.ind apply Quot.sound trivial /-! # Relations -/ class Antisymm {α : Sort u} (r : α → α → Prop) where antisymm {a b : α} : r a b → r b a → a = b namespace Lean /-! # Kernel reduction hints -/ /-- When the kernel tries to reduce a term `Lean.reduceBool c`, it will invoke the Lean interpreter to evaluate `c`. The kernel will not use the interpreter if `c` is not a constant. This feature is useful for performing proofs by reflection. Remark: the Lean frontend allows terms of the from `Lean.reduceBool t` where `t` is a term not containing free variables. The frontend automatically declares a fresh auxiliary constant `c` and replaces the term with `Lean.reduceBool c`. The main motivation is that the code for `t` will be pre-compiled. Warning: by using this feature, the Lean compiler and interpreter become part of your trusted code base. This is extra 30k lines of code. More importantly, you will probably not be able to check your developement using external type checkers (e.g., Trepplein) that do not implement this feature. Keep in mind that if you are using Lean as programming language, you are already trusting the Lean compiler and interpreter. So, you are mainly losing the capability of type checking your developement using external checkers. Recall that the compiler trusts the correctness of all `[implementedBy ...]` and `[extern ...]` annotations. If an extern function is executed, then the trusted code base will also include the implementation of the associated foreign function. -/ opaque reduceBool (b : Bool) : Bool := b /-- Similar to `Lean.reduceBool` for closed `Nat` terms. Remark: we do not have plans for supporting a generic `reduceValue {α} (a : α) : α := a`. The main issue is that it is non-trivial to convert an arbitrary runtime object back into a Lean expression. We believe `Lean.reduceBool` enables most interesting applications (e.g., proof by reflection). -/ opaque reduceNat (n : Nat) : Nat := n axiom ofReduceBool (a b : Bool) (h : reduceBool a = b) : a = b axiom ofReduceNat (a b : Nat) (h : reduceNat a = b) : a = b class IsAssociative {α : Sort u} (op : α → α → α) where assoc : (a b c : α) → op (op a b) c = op a (op b c) class IsCommutative {α : Sort u} (op : α → α → α) where comm : (a b : α) → op a b = op b a class IsIdempotent {α : Sort u} (op : α → α → α) where idempotent : (x : α) → op x x = x class IsNeutral {α : Sort u} (op : α → α → α) (neutral : α) where left_neutral : (a : α) → op neutral a = a right_neutral : (a : α) → op a neutral = a end Lean