/- Copyright (c) 2018 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura -/ prelude import init.data.nat.basic init.data.fin.basic init.data.uint init.data.repr init.function import init.data.tostring universes u v w /- The Compiler has special support for arrays. They are implemented as a dynamic Array. -/ -- TODO(Leo): mark as opaque structure Array (α : Type u) := (sz : Nat) (data : Fin sz → α) attribute [extern cpp inline "lean::array_sz(#2)"] Array.sz @[extern cpp inline "lean::array_get_size(#2)"] def Array.size {α : Type u} (a : @& Array α) : Nat := a.sz @[extern cpp inline "lean::mk_array(#2, #3)"] def mkArray {α : Type u} (n : Nat) (v : α) : Array α := { sz := n, data := λ _, v} theorem szMkArrayEq {α : Type u} (n : Nat) (v : α) : (mkArray n v).sz = n := rfl namespace Array variables {α : Type u} {β : Type v} @[extern cpp inline "lean::mk_nil_array()"] def mkNil (_ : Unit) : Array α := { sz := 0, data := λ ⟨x, h⟩, absurd h (Nat.notLtZero x) } def empty : Array α := mkNil () def isEmpty (a : Array α) : Bool := a.size = 0 @[extern cpp inline "lean::array_read(#2, #3)"] def read (a : @& Array α) (i : @& Fin a.sz) : α := a.data i @[extern cpp inline "lean::array_write(#2, #3, #4)"] def write (a : Array α) (i : @& Fin a.sz) (v : α) : Array α := { sz := a.sz, data := λ j, if h : i = j then v else a.data j } theorem szWriteEq (a : Array α) (i : Fin a.sz) (v : α) : (write a i v).sz = a.sz := rfl @[extern cpp inline "lean::array_safe_read(#2, #3, #4)"] def read' [Inhabited α] (a : @& Array α) (i : @& Nat) : α := if h : i < a.sz then a.read ⟨i, h⟩ else default α @[extern cpp inline "lean::array_safe_write(#2, #3, #4)"] def write' (a : Array α) (i : @& Nat) (v : α) : Array α := if h : i < a.sz then a.write ⟨i, h⟩ v else a @[extern cpp inline "lean::array_uread(#2, #3)"] def uread (a : @& Array α) (i : USize) (h : i.toNat < a.sz) : α := a.read ⟨i.toNat, h⟩ @[extern cpp inline "lean::array_uwrite(#2, #3, #4)"] def uwrite (a : @& Array α) (i : USize) (v : @& α) (h : i.toNat < a.sz) : Array α := a.write ⟨i.toNat, h⟩ v @[extern cpp inline "lean::array_safe_uread(#2, #3, #4)"] def uread' [Inhabited α] (a : Array α) (i : USize) : α := if h : i.toNat < a.sz then a.read ⟨i.toNat, h⟩ else default α @[extern cpp inline "lean::array_safe_uwrite(#2, #3, #4)"] def uwrite' (a : Array α) (i : USize) (v : α) : Array α := if h : i.toNat < a.sz then a.write ⟨i.toNat, h⟩ v else a @[extern cpp inline "lean::array_push(#2, #3)"] def push (a : Array α) (v : α) : Array α := { sz := Nat.succ a.sz, data := λ ⟨j, h₁⟩, if h₂ : j = a.sz then v else a.data ⟨j, Nat.ltOfLeOfNe (Nat.leOfLtSucc h₁) h₂⟩ } @[extern cpp inline "lean::array_pop(#2)"] def pop (a : Array α) : Array α := { sz := Nat.pred a.sz, data := λ ⟨j, h⟩, a.read ⟨j, Nat.ltOfLtOfLe h (Nat.predLe _)⟩ } -- TODO(Leo): justify termination using wf-rec @[specialize] private def iterateAux (a : Array α) (f : Π i : Fin a.sz, α → β → β) : Nat → β → β | i b := if h : i < a.sz then let idx : Fin a.sz := ⟨i, h⟩ in iterateAux (i+1) (f idx (a.read idx) b) else b @[inline] def iterate (a : Array α) (b : β) (f : Π i : Fin a.sz, α → β → β) : β := iterateAux a f 0 b @[inline] def foldl (a : Array α) (b : β) (f : α → β → β) : β := iterate a b (λ _, f) @[specialize] private def revIterateAux (a : Array α) (f : Π i : Fin a.sz, α → β → β) : Π (i : Nat), i ≤ a.sz → β → β | 0 h b := b | (j+1) h b := let i : Fin a.sz := ⟨j, h⟩ in revIterateAux j (Nat.leOfLt h) (f i (a.read i) b) @[inline] def revIterate (a : Array α) (b : β) (f : Π i : Fin a.sz, α → β → β) : β := revIterateAux a f a.size (Nat.leRefl _) b @[inline] def revFoldl (a : Array α) (b : β) (f : α → β → β) : β := revIterate a b (λ _, f) def toList (a : Array α) : List α := a.revFoldl [] (::) instance [HasRepr α] : HasRepr (Array α) := ⟨repr ∘ toList⟩ instance [HasToString α] : HasToString (Array α) := ⟨toString ∘ toList⟩ @[inline] private def foreachAux (a : Array α) (f : Π i : Fin a.sz, α → α) : { a' : Array α // a'.sz = a.sz } := iterate a ⟨a, rfl⟩ $ λ i v ⟨a', h⟩, let i' : Fin a'.sz := Eq.recOn h.symm i in ⟨a'.write i' (f i v), (szWriteEq a' i' (f i v)) ▸ h⟩ @[inline] def foreach (a : Array α) (f : Π i : Fin a.sz, α → α) : Array α := (foreachAux a f).val theorem szForeachEq (a : Array α) (f : Π i : Fin a.sz, α → α) : (foreach a f).sz = a.sz := (foreachAux a f).property @[inline] def map (f : α → α) (a : Array α) : Array α := foreach a (λ _, f) @[inline] def map₂ (f : α → α → α) (a b : Array α) : Array α := if h : a.size ≤ b.size then foreach a (λ ⟨i, h'⟩, f (b.read ⟨i, Nat.ltOfLtOfLe h' h⟩)) else foreach b (λ ⟨i, h'⟩, f (a.read ⟨i, Nat.ltTrans h' (Nat.gtOfNotLe h)⟩)) end Array def List.toArrayAux {α : Type u} : List α → Array α → Array α | [] r := r | (a::as) r := List.toArrayAux as (r.push a) def List.toArray {α : Type u} (l : List α) : Array α := l.toArrayAux Array.empty