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/-
Copyright (c) 2017 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.repr init.data.option.basic
universes u v w w'
inductive Rbcolor
| red | black
inductive RBNode (α : Type u) (β : α → Type v)
| leaf {} : RBNode
| node (color : Rbcolor) (lchild : RBNode) (key : α) (val : β key) (rchild : RBNode) : RBNode
namespace RBNode
variables {α : Type u} {β : α → Type v} {σ : Type w}
open Rbcolor Nat
def depth (f : Nat → Nat → Nat) : RBNode α β → Nat
| leaf => 0
| node _ l _ _ r => succ (f (depth l) (depth r))
protected def min : RBNode α β → Option (Sigma (fun k => β k))
| leaf => none
| node _ leaf k v _ => some ⟨k, v⟩
| node _ l k v _ => min l
protected def max : RBNode α β → Option (Sigma (fun k => β k))
| leaf => none
| node _ _ k v leaf => some ⟨k, v⟩
| node _ _ k v r => max r
@[specialize] def fold (f : σ → ∀ (k : α), β k → σ) : σ → RBNode α β → σ
| b, leaf => b
| b, node _ l k v r => fold (f (fold b l) k v) r
@[specialize] def mfold {m : Type w → Type w'} [Monad m] (f : σ → ∀ (k : α), β k → m σ) : σ → RBNode α β → m σ
| b, leaf => pure b
| b, node _ l k v r => do
b ← mfold b l;
b ← f b k v;
mfold b r
@[specialize] def revFold (f : σ → ∀ (k : α), β k → σ) : σ → RBNode α β → σ
| b, leaf => b
| b, node _ l k v r => revFold (f (revFold b r) k v) l
@[specialize] def all (p : ∀ k, β k → Bool) : RBNode α β → Bool
| leaf => true
| node _ l k v r => p k v && all l && all r
@[specialize] def any (p : ∀ k, β k → Bool) : RBNode α β → Bool
| leaf => false
| node _ l k v r => p k v || any l || any r
def singleton (k : α) (v : β k) : RBNode α β :=
node red leaf k v leaf
@[inline] def balance1 : ∀ a, β a → RBNode α β → RBNode α β → RBNode α β
| kv, vv, t, node _ (node red l kx vx r₁) ky vy r₂ => node red (node black l kx vx r₁) ky vy (node black r₂ kv vv t)
| kv, vv, t, node _ l₁ ky vy (node red l₂ kx vx r) => node red (node black l₁ ky vy l₂) kx vx (node black r kv vv t)
| kv, vv, t, node _ l ky vy r => node black (node red l ky vy r) kv vv t
| _, _, _, _ => leaf -- unreachable
@[inline] def balance2 : RBNode α β → ∀ a, β a → RBNode α β → RBNode α β
| t, kv, vv, node _ (node red l kx₁ vx₁ r₁) ky vy r₂ => node red (node black t kv vv l) kx₁ vx₁ (node black r₁ ky vy r₂)
| t, kv, vv, node _ l₁ ky vy (node red l₂ kx₂ vx₂ r₂) => node red (node black t kv vv l₁) ky vy (node black l₂ kx₂ vx₂ r₂)
| t, kv, vv, node _ l ky vy r => node black t kv vv (node red l ky vy r)
| _, _, _, _ => leaf -- unreachable
def isRed : RBNode α β → Bool
| node red _ _ _ _ => true
| _ => false
def isBlack : RBNode α β → Bool
| node black _ _ _ _ => true
| _ => false
section Insert
variables (lt : αα → Bool)
@[specialize] def ins : RBNode α β → ∀ k, β k → RBNode α β
| leaf, kx, vx => node red leaf kx vx leaf
| node red a ky vy b, kx, vx =>
if lt kx ky then node red (ins a kx vx) ky vy b
else if lt ky kx then node red a ky vy (ins b kx vx)
else node red a kx vx b
| node black a ky vy b, kx, vx =>
if lt kx ky then
if isRed a then balance1 ky vy b (ins a kx vx)
else node black (ins a kx vx) ky vy b
else if lt ky kx then
if isRed b then balance2 a ky vy (ins b kx vx)
else node black a ky vy (ins b kx vx)
else
node black a kx vx b
def setBlack : RBNode α β → RBNode α β
| node _ l k v r => node black l k v r
| e => e
@[specialize] def insert (t : RBNode α β) (k : α) (v : β k) : RBNode α β :=
if isRed t then setBlack (ins lt t k v)
else ins lt t k v
end Insert
def balance₃ : RBNode α β → ∀ k, β k → RBNode α β → RBNode α β
| node red (node red a kx vx b) ky vy c, k, v, d => node red (node black a kx vx b) ky vy (node black c k v d)
| node red a kx vx (node red b ky vy c), k, v, d => node red (node black a kx vx b) ky vy (node black c k v d)
| a, k, v, node red b ky vy (node red c kz vz d) => node red (node black a k v b) ky vy (node black c kz vz d)
| a, k, v, node red (node red b ky vy c) kz vz d => node red (node black a k v b) ky vy (node black c kz vz d)
| l, k, v, r => node black l k v r
def setRed : RBNode α β → RBNode α β
| node _ a k v b => node red a k v b
| e => e
def balLeft : RBNode α β → ∀ k, β k → RBNode α β → RBNode α β
| node red a kx vx b, k, v, r => node red (node black a kx vx b) k v r
| l, k, v, node black a ky vy b => balance₃ l k v (node red a ky vy b)
| l, k, v, node red (node black a ky vy b) kz vz c => node red (node black l k v a) ky vy (balance₃ b kz vz (setRed c))
| l, k, v, r => node red l k v r -- unreachable
def balRight (l : RBNode α β) (k : α) (v : β k) (r : RBNode α β) : RBNode α β :=
match r with
| (node red b ky vy c) => node red l k v (node black b ky vy c)
| _ => match l with
| node black a kx vx b => balance₃ (node red a kx vx b) k v r
| node red a kx vx (node black b ky vy c) => node red (balance₃ (setRed a) kx vx b) ky vy (node black c k v r)
| _ => node red l k v r -- unreachable
-- TODO: use wellfounded recursion
partial def appendTrees : RBNode α β → RBNode α β → RBNode α β
| leaf, x => x
| x, leaf => x
| node red a kx vx b, node red c ky vy d =>
match appendTrees b c with
| node red b' kz vz c' => node red (node red a kx vx b') kz vz (node red c' ky vy d)
| bc => node red a kx vx (node red bc ky vy d)
| node black a kx vx b, node black c ky vy d =>
match appendTrees b c with
| node red b' kz vz c' => node red (node black a kx vx b') kz vz (node black c' ky vy d)
| bc => balLeft a kx vx (node black bc ky vy d)
| a, node red b kx vx c => node red (appendTrees a b) kx vx c
| node red a kx vx b, c => node red a kx vx (appendTrees b c)
section Erase
variables (lt : αα → Bool)
@[specialize] def del (x : α) : RBNode α β → RBNode α β
| leaf => leaf
| node _ a y v b =>
if lt x y then
if a.isBlack then balLeft (del a) y v b
else node red (del a) y v b
else if lt y x then
if b.isBlack then balRight a y v (del b)
else node red a y v (del b)
else appendTrees a b
@[specialize] def erase (x : α) (t : RBNode α β) : RBNode α β :=
let t := del lt x t;
t.setBlack
end Erase
section Membership
variable (lt : αα → Bool)
@[specialize] def findCore : RBNode α β → ∀ (k : α), Option (Sigma (fun k => β k))
| leaf, x => none
| node _ a ky vy b, x =>
if lt x ky then findCore a x
else if lt ky x then findCore b x
else some ⟨ky, vy⟩
@[specialize] def find {β : Type v} : RBNode α (fun _ => β) → α → Option β
| leaf, x => none
| node _ a ky vy b, x =>
if lt x ky then find a x
else if lt ky x then find b x
else some vy
@[specialize] def lowerBound : RBNode α β → α → Option (Sigma β) → Option (Sigma β)
| leaf, x, lb => lb
| node _ a ky vy b, x, lb =>
if lt x ky then lowerBound a x lb
else if lt ky x then lowerBound b x (some ⟨ky, vy⟩)
else some ⟨ky, vy⟩
end Membership
inductive WellFormed (lt : αα → Bool) : RBNode α β → Prop
| leafWff : WellFormed leaf
| insertWff {n n' : RBNode α β} {k : α} {v : β k} : WellFormed n → n' = insert lt n k v → WellFormed n'
| eraseWff {n n' : RBNode α β} {k : α} : WellFormed n → n' = erase lt k n → WellFormed n'
end RBNode
open RBNode
/- TODO(Leo): define dRBMap -/
def RBMap (α : Type u) (β : Type v) (lt : αα → Bool) : Type (max u v) :=
{t : RBNode α (fun _ => β) // t.WellFormed lt }
@[inline] def mkRBMap (α : Type u) (β : Type v) (lt : αα → Bool) : RBMap α β lt :=
⟨leaf, WellFormed.leafWff lt⟩
@[inline] def RBMap.empty {α : Type u} {β : Type v} {lt : αα → Bool} : RBMap α β lt :=
mkRBMap _ _ _
instance (α : Type u) (β : Type v) (lt : αα → Bool) : HasEmptyc (RBMap α β lt) :=
⟨RBMap.empty⟩
namespace RBMap
variables {α : Type u} {β : Type v} {σ : Type w} {lt : αα → Bool}
def depth (f : Nat → Nat → Nat) (t : RBMap α β lt) : Nat :=
t.val.depth f
@[inline] def fold (f : σα → β → σ) : σ → RBMap α β lt → σ
| b, ⟨t, _⟩ => t.fold f b
@[inline] def revFold (f : σα → β → σ) : σ → RBMap α β lt → σ
| b, ⟨t, _⟩ => t.revFold f b
@[inline] def mfold {m : Type w → Type w'} [Monad m] (f : σα → β → m σ) : σ → RBMap α β lt → m σ
| b, ⟨t, _⟩ => t.mfold f b
@[inline] def mfor {m : Type w → Type w'} [Monad m] (f : α → β → m σ) (t : RBMap α β lt) : m PUnit :=
t.mfold (fun _ k v => f k v *> pure ⟨⟩) ⟨⟩
@[inline] def isEmpty : RBMap α β lt → Bool
| ⟨leaf, _⟩ => true
| _ => false
@[specialize] def toList : RBMap α β lt → List (α × β)
| ⟨t, _⟩ => t.revFold (fun ps k v => (k, v)::ps) []
@[inline] protected def min : RBMap α β lt → Option (α × β)
| ⟨t, _⟩ =>
match t.min with
| some ⟨k, v⟩ => some (k, v)
| none => none
@[inline] protected def max : RBMap α β lt → Option (α × β)
| ⟨t, _⟩ =>
match t.max with
| some ⟨k, v⟩ => some (k, v)
| none => none
instance [HasRepr α] [HasRepr β] : HasRepr (RBMap α β lt) :=
⟨fun t => "rbmapOf " ++ repr t.toList⟩
@[inline] def insert : RBMap α β lt → α → β → RBMap α β lt
| ⟨t, w⟩, k, v => ⟨t.insert lt k v, WellFormed.insertWff w rfl⟩
@[inline] def erase : RBMap α β lt → α → RBMap α β lt
| ⟨t, w⟩, k => ⟨t.erase lt k, WellFormed.eraseWff w rfl⟩
@[specialize] def ofList : List (α × β) → RBMap α β lt
| [] => mkRBMap _ _ _
| ⟨k,v⟩::xs => (ofList xs).insert k v
@[inline] def findCore : RBMap α β lt → α → Option (Sigma (fun (k : α) => β))
| ⟨t, _⟩, x => t.findCore lt x
@[inline] def find : RBMap α β lt → α → Option β
| ⟨t, _⟩, x => t.find lt x
/-- (lowerBound k) retrieves the kv pair of the largest key smaller than or equal to `k`,
if it exists. -/
@[inline] def lowerBound : RBMap α β lt → α → Option (Sigma (fun (k : α) => β))
| ⟨t, _⟩, x => t.lowerBound lt x none
@[inline] def contains (t : RBMap α β lt) (a : α) : Bool :=
(t.find a).isSome
@[inline] def fromList (l : List (α × β)) (lt : αα → Bool) : RBMap α β lt :=
l.foldl (fun r p => r.insert p.1 p.2) (mkRBMap α β lt)
@[inline] def all : RBMap α β lt → (α → β → Bool) → Bool
| ⟨t, _⟩, p => t.all p
@[inline] def any : RBMap α β lt → (α → β → Bool) → Bool
| ⟨t, _⟩, p => t.any p
def size (m : RBMap α β lt) : Nat :=
m.fold (fun sz _ _ => sz+1) 0
def maxDepth (t : RBMap α β lt) : Nat :=
t.val.depth Nat.max
end RBMap
def rbmapOf {α : Type u} {β : Type v} (l : List (α × β)) (lt : αα → Bool) : RBMap α β lt :=
RBMap.fromList l lt
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