/- 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 import init.data.repr init.data.tostring init.control.id universes u v w /- The Compiler has special support for arrays. They are implemented using dynamic arrays: https://en.wikipedia.org/wiki/Dynamic_array -/ structure Array (α : Type u) := (sz : Nat) (data : Fin sz → α) attribute [extern cpp inline "lean::array_sz(#2)"] Array.sz @[reducible, extern cpp inline "lean::array_get_size(#2)"] def Array.size {α : Type u} (a : @& Array α) : Nat := a.sz namespace Array variables {α : Type u} {β : Type v} {σ : Type w} /- The parameter `c` is the initial capacity -/ @[extern cpp inline "lean::mk_empty_array(#2)"] def mkEmpty (c : @& Nat) : Array α := { sz := 0, data := λ ⟨x, h⟩, absurd h (Nat.notLtZero x) } @[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::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 def empty : Array α := mkEmpty 0 instance : HasEmptyc (Array α) := ⟨Array.empty⟩ instance : Inhabited (Array α) := ⟨Array.empty⟩ def isEmpty (a : Array α) : Bool := a.size = 0 def singleton (v : α) : Array α := mkArray 1 v @[extern cpp inline "lean::array_fget(#2, #3)"] def fget (a : @& Array α) (i : @& Fin a.size) : α := a.data i /- Low-level version of `fget` which is as fast as a C array read. `Fin` values are represented as tag pointers in the Lean runtime. Thus, `fget` may be slightly slower than `uget`. -/ @[extern cpp inline "lean::array_uget(#2, #3)"] def uget (a : @& Array α) (i : USize) (h : i.toNat < a.size) : α := a.fget ⟨i.toNat, h⟩ /- "Comfortable" version of `fget`. It performs a bound check at runtime. -/ @[extern cpp inline "lean::array_get(#2, #3, #4)"] def get [Inhabited α] (a : @& Array α) (i : @& Nat) : α := if h : i < a.size then a.fget ⟨i, h⟩ else default α def back [Inhabited α] (a : Array α) : α := a.get (a.size - 1) def getOpt (a : Array α) (i : Nat) : Option α := if h : i < a.size then some (a.fget ⟨i, h⟩) else none @[extern cpp inline "lean::array_fset(#2, #3, #4)"] def fset (a : Array α) (i : @& Fin a.size) (v : α) : Array α := { sz := a.sz, data := λ j, if h : i = j then v else a.data j } theorem szFSetEq (a : Array α) (i : Fin a.size) (v : α) : (fset a i v).size = a.size := rfl /- Low-level version of `fset` which is as fast as a C array fset. `Fin` values are represented as tag pointers in the Lean runtime. Thus, `fset` may be slightly slower than `uset`. -/ @[extern cpp inline "lean::array_uset(#2, #3, #4)"] def uset (a : Array α) (i : USize) (v : α) (h : i.toNat < a.size) : Array α := a.fset ⟨i.toNat, h⟩ v /- "Comfortable" version of `fset`. It performs a bound check at runtime. -/ @[extern cpp inline "lean::array_set(#2, #3, #4)"] def set (a : Array α) (i : @& Nat) (v : α) : Array α := if h : i < a.size then a.fset ⟨i, h⟩ v else a @[extern cpp inline "lean::array_fswap(#2, #3, #4)"] def fswap (a : Array α) (i j : @& Fin a.size) : Array α := let v₁ := a.fget i in let v₂ := a.fget j in let a := a.fset i v₂ in a.fset j v₁ @[extern cpp inline "lean::array_swap(#2, #3, #4)"] def swap (a : Array α) (i j : @& Nat) : Array α := if h₁ : i < a.size then if h₂ : j < a.size then fswap a ⟨i, h₁⟩ ⟨j, h₂⟩ else a else a @[inline] def fswapAt {α : Type} (a : Array α) (i : Fin a.size) (v : α) : α × Array α := let e := a.fget i in let a := a.fset i v in (e, a) @[inline] def swapAt {α : Type} (a : Array α) (i : Nat) (v : α) : α × Array α := if h : i < a.size then fswapAt a ⟨i, h⟩ v else (v, a) @[extern cpp inline "lean::array_pop(#2)"] def pop (a : Array α) : Array α := { sz := Nat.pred a.size, data := λ ⟨j, h⟩, a.fget ⟨j, Nat.ltOfLtOfLe h (Nat.predLe _)⟩ } -- TODO(Leo): justify termination using wf-rec partial def shrink : Array α → Nat → Array α | a n := if n ≥ a.size then a else shrink a.pop n section variables {m : Type v → Type v} [Monad m] local attribute [instance] monadInhabited' -- TODO(Leo): justify termination using wf-rec @[specialize] partial def miterateAux (a : Array α) (f : Π i : Fin a.size, α → β → m β) : Nat → β → m β | i b := if h : i < a.size then let idx : Fin a.size := ⟨i, h⟩ in f idx (a.fget idx) b >>= miterateAux (i+1) else pure b @[inline] def miterate (a : Array α) (b : β) (f : Π i : Fin a.size, α → β → m β) : m β := miterateAux a f 0 b @[inline] def mfoldl (a : Array α) (b : β) (f : β → α → m β) : m β := miterate a b (λ _ b a, f a b) @[inline] def mfoldlFrom (a : Array α) (b : β) (f : β → α → m β) (ini : Nat := 0) : m β := miterateAux a (λ _ b a, f a b) ini b -- TODO(Leo): justify termination using wf-rec @[specialize] partial def miterate₂Aux (a₁ : Array α) (a₂ : Array σ) (f : Π i : Fin a₁.size, α → σ → β → m β) : Nat → β → m β | i b := if h₁ : i < a₁.size then let idx₁ : Fin a₁.size := ⟨i, h₁⟩ in if h₂ : i < a₂.size then let idx₂ : Fin a₂.size := ⟨i, h₂⟩ in f idx₁ (a₁.fget idx₁) (a₂.fget idx₂) b >>= miterate₂Aux (i+1) else pure b else pure b @[inline] def miterate₂ (a₁ : Array α) (a₂ : Array σ) (b : β) (f : Π i : Fin a₁.size, α → σ → β → m β) : m β := miterate₂Aux a₁ a₂ f 0 b @[inline] def mfoldl₂ (a₁ : Array α) (a₂ : Array σ) (b : β) (f : β → α → σ → m β) : m β := miterate₂ a₁ a₂ b (λ _ a₁ a₂ b, f b a₁ a₂) local attribute [instance] monadInhabited -- TODO(Leo): justify termination using wf-rec @[specialize] partial def mfindAux (a : Array α) (f : α → m (Option β)) : Nat → m (Option β) | i := if h : i < a.size then let idx : Fin a.size := ⟨i, h⟩ in do r ← f (a.fget idx), match r with | some v := pure r | none := mfindAux (i+1) else pure none @[inline] def mfind (a : Array α) (f : α → m (Option β)) : m (Option β) := mfindAux a f 0 end @[inline] def iterate (a : Array α) (b : β) (f : Π i : Fin a.size, α → β → β) : β := Id.run $ miterateAux a f 0 b @[inline] def iterateFrom (a : Array α) (b : β) (i : Nat) (f : Π i : Fin a.size, α → β → β) : β := Id.run $ miterateAux a f i b @[inline] def foldl (a : Array α) (f : β → α → β) (b : β) : β := iterate a b (λ _ a b, f b a) @[inline] def foldlFrom (a : Array α) (f : β → α → β) (b : β) (ini : Nat := 0) : β := Id.run $ mfoldlFrom a b f ini @[inline] def iterate₂ (a₁ : Array α) (a₂ : Array σ) (b : β) (f : Π i : Fin a₁.size, α → σ → β → β) : β := Id.run $ miterate₂Aux a₁ a₂ f 0 b @[inline] def foldl₂ (a₁ : Array α) (a₂ : Array σ) (f : β → α → σ → β) (b : β) : β := iterate₂ a₁ a₂ b (λ _ a₁ a₂ b, f b a₁ a₂) @[inline] def find (a : Array α) (f : α → Option β) : Option β := Id.run $ mfindAux a f 0 section variables {m : Type → Type v} [Monad m] local attribute [instance] monadInhabited @[specialize] partial def anyMAux (a : Array α) (p : α → m Bool) : Nat → m Bool | i := if h : i < a.size then let idx : Fin a.size := ⟨i, h⟩ in do b ← p (a.fget idx), match b with | true := pure true | false := anyMAux (i+1) else pure false @[inline] def anyM (a : Array α) (p : α → m Bool) : m Bool := anyMAux a p 0 @[inline] def allM (a : Array α) (p : α → m Bool) : m Bool := not <$> anyM a (λ v, not <$> p v) end @[inline] def any (a : Array α) (p : α → Bool) : Bool := Id.run $ anyM a p @[inline] def all (a : Array α) (p : α → Bool) : Bool := !any a (λ v, !p v) @[specialize] private def revIterateAux (a : Array α) (f : Π i : Fin a.size, α → β → β) : Π (i : Nat), i ≤ a.size → β → β | 0 h b := b | (j+1) h b := let i : Fin a.size := ⟨j, h⟩ in revIterateAux j (Nat.leOfLt h) (f i (a.fget i) b) @[inline] def revIterate (a : Array α) (b : β) (f : Π i : Fin a.size, 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⟩ section variables {m : Type u → Type u} [Monad m] @[inline] def mmap {β : Type u} (f : α → m β) (as : Array α) : m (Array β) := as.mfoldl (mkEmpty as.size) (λ bs a, do b ← f a, pure (bs.push b)) end @[inline] def modify [Inhabited α] (a : Array α) (i : Nat) (f : α → α) : Array α := if h : i < a.size then let idx : Fin a.size := ⟨i, h⟩ in let v := a.fget idx in let a := a.fset idx (default α) in let v := f v in a.fset idx v else a section variables {m : Type u → Type v} [Monad m] [Inhabited α] local attribute [instance] monadInhabited' @[specialize] partial def hmmapAux (f : Nat → α → m α) : Nat → Array α → m (Array α) | i a := if h : i < a.size then let idx : Fin a.size := ⟨i, h⟩ in let v : α := a.fget idx in let a := a.fset idx (default α) in do v ← f i v, hmmapAux (i+1) (a.fset idx v) else pure a /- Homogeneous `mmap` -/ @[inline] def hmmap (f : α → m α) (a : Array α) : m (Array α) := hmmapAux (λ _, f) 0 a end /- Homogeneous map -/ @[inline] def hmap [Inhabited α] (f : α → α) (a : Array α) : Array α := Id.run $ hmmap f a @[inline] def hmapIdx [Inhabited α] (f : Nat → α → α) (a : Array α) : Array α := Id.run $ hmmapAux f 0 a @[inline] def map (f : α → β) (as : Array α) : Array β := as.foldl (λ bs a, bs.push (f a)) (mkEmpty as.size) section variables {m : Type u → Type u} [Monad m] local attribute [instance] monadInhabited @[specialize] partial def mforAux {α : Type w} {β : Type u} (f : α → m β) (a : Array α) : Nat → m PUnit | i := if h : i < a.size then let idx : Fin a.size := ⟨i, h⟩ in let v : α := a.fget idx in f v *> mforAux (i+1) else pure ⟨⟩ def mfor {α : Type w} {β : Type u} (f : α → m β) (a : Array α) : m PUnit := a.mforAux f 0 end -- TODO(Leo): justify termination using wf-rec partial def extractAux (a : Array α) : Nat → Π (e : Nat), e ≤ a.size → Array α → Array α | i e hle r := if hlt : i < e then let idx : Fin a.size := ⟨i, Nat.ltOfLtOfLe hlt hle⟩ in extractAux (i+1) e hle (r.push (a.fget idx)) else r def extract (a : Array α) (b e : Nat) : Array α := let r : Array α := mkEmpty (e - b) in if h : e ≤ a.size then extractAux a b e h r else r protected def append (a : Array α) (b : Array α) : Array α := b.foldl (λ a v, a.push v) a instance : HasAppend (Array α) := ⟨Array.append⟩ -- TODO(Leo): justify termination using wf-rec partial def isEqvAux (a b : Array α) (hsz : a.size = b.size) (p : α → α → Bool) : Nat → Bool | i := if h : i < a.size then let aidx : Fin a.size := ⟨i, h⟩ in let bidx : Fin b.size := ⟨i, hsz ▸ h⟩ in match p (a.fget aidx) (b.fget bidx) with | true := isEqvAux (i+1) | false := false else true @[specialize] def isEqv (a b : Array α) (p : α → α → Bool) : Bool := if h : a.size = b.size then isEqvAux a b h p 0 else false instance [HasBeq α] : HasBeq (Array α) := ⟨λ a b, isEqv a b (==)⟩ -- TODO(Leo): justify termination using wf-rec, and use `fswap` partial def reverseAux : Array α → Nat → Array α | a i := let n := a.size in if i < n / 2 then reverseAux (a.swap i (n - i - 1)) (i+1) else a def reverse (a : Array α) : Array α := reverseAux a 0 -- TODO(Leo): justify termination using wf-rec @[specialize] partial def filterAux (p : α → Bool) : Array α → Nat → Nat → Array α | a i j := if h₁ : i < a.size then if p (a.fget ⟨i, h₁⟩) then if h₂ : j < i then filterAux (a.fswap ⟨i, h₁⟩ ⟨j, Nat.ltTrans h₂ h₁⟩) (i+1) (j+1) else filterAux a (i+1) (j+1) else filterAux a (i+1) j else a.shrink j @[inline] def filter (p : α → Bool) (as : Array α) : Array α := filterAux p as 0 0 end Array export Array (mkArray) @[inlineIfReduce] def List.toArrayAux {α : Type u} : List α → Array α → Array α | [] r := r | (a::as) r := List.toArrayAux as (r.push a) @[inlineIfReduce] def List.redLength {α : Type u} : List α → Nat | [] := 0 | (_::as) := as.redLength + 1 @[inline] def List.toArray {α : Type u} (as : List α) : Array α := as.toArrayAux (Array.mkEmpty as.redLength)