Documentation

Init.Data.List.Impl

Tail recursive implementations for `List` definitions. #

Many of the proofs require theorems about Array, so these are in a separate file to minimize imports.

If you import Init.Data.List.Basic but do not import this file, then at runtime you will get non-tail recursive versions of the following definitions.

Basic `List` operations. #

The following operations are already tail-recursive, and do not need @[csimp] replacements: get, foldl, beq, isEqv, reverse, elem (and hence contains), drop, dropWhile, partition, isPrefixOf, isPrefixOf?, find?, findSome?, lookup, any (and hence or), all (and hence and) , range, eraseDups, eraseReps, span, groupBy.

The following operations are still missing @[csimp] replacements: concat, zipWithAll.

The following operations are not recursive to begin with (or are defined in terms of recursive primitives): isEmpty, isSuffixOf, isSuffixOf?, rotateLeft, rotateRight, insert, zip, enum, minimum?, maximum?, and removeAll.

The following operations were already given @[csimp] replacements in Init/Data/List/Basic.lean: length, map, filter, replicate, leftPad, unzip, range', iota, intersperse.

The following operations are given @[csimp] replacements below: ``set, filterMap, foldr, append, bind, join, take, takeWhile, dropLast, replace, erase, eraseIdx, zipWith, , enumFrom, and intercalate`.

set #

@[inline]

def List.setTR {α : Type u_1} (l : List α) (n : Nat) (a : α) :

Tail recursive version of List.set.

Equations

l.setTR n a = List.setTR.go l a l n #[]

Instances For

def List.setTR.go {α : Type u_1} (l : List α) (a : α) :

List α → Nat → Array α → List α

Auxiliary for setTR: setTR.go l a xs n acc = acc.toList ++ set xs a, unless n ≥ l.length in which case it returns l

Equations

List.setTR.go l a [] x✝ x = l
List.setTR.go l a (head :: xs) 0 x = x.toListAppend (a :: xs)
List.setTR.go l a (x_3 :: xs) n.succ x = List.setTR.go l a xs n (x.push x_3)

Instances For

@[csimp]

theorem List.set_eq_setTR :

@List.set = @List.setTR

theorem List.set_eq_setTR.go (α : Type u_1) (l : List α) (a : α) (acc : Array α) (xs : List α) (n : Nat) :

l = acc.data ++ xs → List.setTR.go l a xs n acc = acc.data ++ xs.set n a

filterMap #

@[inline]

def List.filterMapTR {α : Type u_1} {β : Type u_2} (f : α → Option β) (l : List α) :

Tail recursive version of filterMap.

Equations

List.filterMapTR f l = List.filterMapTR.go f l #[]

Instances For

@[specialize #[]]

def List.filterMapTR.go {α : Type u_1} {β : Type u_2} (f : α → Option β) :

List α → Array β → List β

Auxiliary for filterMap: filterMap.go f l = acc.toList ++ filterMap f l

Equations

List.filterMapTR.go f [] x = x.toList
List.filterMapTR.go f (a :: as) x = match f a with | none => List.filterMapTR.go f as x | some b => List.filterMapTR.go f as (x.push b)

Instances For

@[csimp]

theorem List.filterMap_eq_filterMapTR :

@List.filterMap = @List.filterMapTR

theorem List.filterMap_eq_filterMapTR.go (α : Type u_2) (β : Type u_1) (f : α → Option β) (as : List α) (acc : Array β) :

List.filterMapTR.go f as acc = acc.data ++ List.filterMap f as

foldr #

@[specialize #[]]

def List.foldrTR {α : Type u_1} {β : Type u_2} (f : α → β → β) (init : β) (l : List α) :

β

Tail recursive version of List.foldr.

Equations

List.foldrTR f init l = Array.foldr f init (List.toArray l)

Instances For

@[csimp]

theorem List.foldr_eq_foldrTR :

@List.foldr = @List.foldrTR

bind #

@[inline]

def List.bindTR {α : Type u_1} {β : Type u_2} (as : List α) (f : α → List β) :

Tail recursive version of List.bind.

Equations

as.bindTR f = List.bindTR.go f as #[]

Instances For

@[specialize #[]]

def List.bindTR.go {α : Type u_1} {β : Type u_2} (f : α → List β) :

List α → Array β → List β

Auxiliary for bind: bind.go f as = acc.toList ++ bind f as

Equations

List.bindTR.go f [] x = x.toList
List.bindTR.go f (a :: as) x = List.bindTR.go f as (x ++ f a)

Instances For

@[csimp]

theorem List.bind_eq_bindTR :

@List.bind = @List.bindTR

theorem List.bind_eq_bindTR.go (α : Type u_2) (β : Type u_1) (f : α → List β) (as : List α) (acc : Array β) :

List.bindTR.go f as acc = acc.data ++ as.bind f

join #

@[inline]

def List.joinTR {α : Type u_1} (l : List (List α)) :

Tail recursive version of List.join.

Equations

l.joinTR = l.bindTR id

Instances For

@[csimp]

theorem List.join_eq_joinTR :

@List.join = @List.joinTR

Sublists #

take #

@[inline]

def List.takeTR {α : Type u_1} (n : Nat) (l : List α) :

Tail recursive version of List.take.

Equations

List.takeTR n l = List.takeTR.go l l n #[]

Instances For

@[specialize #[]]

def List.takeTR.go {α : Type u_1} (l : List α) :

List α → Nat → Array α → List α

Auxiliary for take: take.go l xs n acc = acc.toList ++ take n xs, unless n ≥ xs.length in which case it returns l.

Equations

List.takeTR.go l [] x✝ x = l
List.takeTR.go l (head :: xs) 0 x = x.toList
List.takeTR.go l (x_3 :: xs) n.succ x = List.takeTR.go l xs n (x.push x_3)

Instances For

@[csimp]

theorem List.take_eq_takeTR :

@List.take = @List.takeTR

takeWhile #

@[inline]

def List.takeWhileTR {α : Type u_1} (p : α → Bool) (l : List α) :

Tail recursive version of List.takeWhile.

Equations

List.takeWhileTR p l = List.takeWhileTR.go p l l #[]

Instances For

@[specialize #[]]

def List.takeWhileTR.go {α : Type u_1} (p : α → Bool) (l : List α) :

List α → Array α → List α

Auxiliary for takeWhile: takeWhile.go p l xs acc = acc.toList ++ takeWhile p xs, unless no element satisfying p is found in xs in which case it returns l.

Equations

List.takeWhileTR.go p l [] x = l
List.takeWhileTR.go p l (a :: as) x = bif p a then List.takeWhileTR.go p l as (x.push a) else x.toList

Instances For

@[csimp]

theorem List.takeWhile_eq_takeWhileTR :

@List.takeWhile = @List.takeWhileTR

dropLast #

@[inline]

def List.dropLastTR {α : Type u_1} (l : List α) :

Tail recursive version of dropLast.

Equations

l.dropLastTR = (List.toArray l).pop.toList

Instances For

@[csimp]

theorem List.dropLast_eq_dropLastTR :

@List.dropLast = @List.dropLastTR

Manipulating elements #

replace #

@[inline]

def List.replaceTR {α : Type u_1} [BEq α] (l : List α) (b : α) (c : α) :

Tail recursive version of List.replace.

Equations

l.replaceTR b c = List.replaceTR.go l b c l #[]

Instances For

@[specialize #[]]

def List.replaceTR.go {α : Type u_1} [BEq α] (l : List α) (b : α) (c : α) :

List α → Array α → List α

Auxiliary for replace: replace.go l b c xs acc = acc.toList ++ replace xs b c, unless b is not found in xs in which case it returns l.

Equations

List.replaceTR.go l b c [] x = l
List.replaceTR.go l b c (a :: as) x = bif b == a then x.toListAppend (c :: as) else List.replaceTR.go l b c as (x.push a)

Instances For

@[csimp]

theorem List.replace_eq_replaceTR :

@List.replace = @List.replaceTR

erase #

@[inline]

def List.eraseTR {α : Type u_1} [BEq α] (l : List α) (a : α) :

Tail recursive version of List.erase.

Equations

l.eraseTR a = List.eraseTR.go l a l #[]

Instances For

def List.eraseTR.go {α : Type u_1} [BEq α] (l : List α) (a : α) :

List α → Array α → List α

Auxiliary for eraseTR: eraseTR.go l a xs acc = acc.toList ++ erase xs a, unless a is not present in which case it returns l

Equations

List.eraseTR.go l a [] x = l
List.eraseTR.go l a (a_1 :: as) x = bif a_1 == a then x.toListAppend as else List.eraseTR.go l a as (x.push a_1)

Instances For

@[csimp]

theorem List.erase_eq_eraseTR :

@List.erase = @List.eraseTR

@[inline]

def List.erasePTR {α : Type u_1} (p : α → Bool) (l : List α) :

Tail-recursive version of eraseP.

Equations

List.erasePTR p l = List.erasePTR.go p l l #[]

Instances For

@[specialize #[]]

def List.erasePTR.go {α : Type u_1} (p : α → Bool) (l : List α) :

List α → Array α → List α

Auxiliary for erasePTR: erasePTR.go p l xs acc = acc.toList ++ eraseP p xs, unless xs does not contain any elements satisfying p, where it returns l.

Equations

List.erasePTR.go p l [] x = l
List.erasePTR.go p l (a :: as) x = bif p a then x.toListAppend as else List.erasePTR.go p l as (x.push a)

Instances For

@[csimp]

theorem List.eraseP_eq_erasePTR :

@List.eraseP = @List.erasePTR

theorem List.eraseP_eq_erasePTR.go (α : Type u_1) (p : α → Bool) (l : List α) (acc : Array α) (xs : List α) :

l = acc.data ++ xs → List.erasePTR.go p l xs acc = acc.data ++ List.eraseP p xs

eraseIdx #

@[inline]

def List.eraseIdxTR {α : Type u_1} (l : List α) (n : Nat) :

Tail recursive version of List.eraseIdx.

Equations

l.eraseIdxTR n = List.eraseIdxTR.go l l n #[]

Instances For

def List.eraseIdxTR.go {α : Type u_1} (l : List α) :

List α → Nat → Array α → List α

Auxiliary for eraseIdxTR: eraseIdxTR.go l n xs acc = acc.toList ++ eraseIdx xs a, unless a is not present in which case it returns l

Equations

List.eraseIdxTR.go l [] x✝ x = l
List.eraseIdxTR.go l (head :: xs) 0 x = x.toListAppend xs
List.eraseIdxTR.go l (x_3 :: xs) n.succ x = List.eraseIdxTR.go l xs n (x.push x_3)

Instances For

@[csimp]

theorem List.eraseIdx_eq_eraseIdxTR :

@List.eraseIdx = @List.eraseIdxTR

Zippers #

zipWith #

@[inline]

def List.zipWithTR {α : Type u_1} {β : Type u_2} {γ : Type u_3} (f : α → β → γ) (as : List α) (bs : List β) :

Tail recursive version of List.zipWith.

Equations

List.zipWithTR f as bs = List.zipWithTR.go f as bs #[]

Instances For

def List.zipWithTR.go {α : Type u_1} {β : Type u_2} {γ : Type u_3} (f : α → β → γ) :

List α → List β → Array γ → List γ

Auxiliary for zipWith: zipWith.go f as bs acc = acc.toList ++ zipWith f as bs

Equations

List.zipWithTR.go f (a :: as) (b :: bs) x = List.zipWithTR.go f as bs (x.push (f a b))
List.zipWithTR.go f x✝¹ x✝ x = x.toList

Instances For

@[csimp]

theorem List.zipWith_eq_zipWithTR :

@List.zipWith = @List.zipWithTR

theorem List.zipWith_eq_zipWithTR.go (α : Type u_3) (β : Type u_2) (γ : Type u_1) (f : α → β → γ) (as : List α) (bs : List β) (acc : Array γ) :

List.zipWithTR.go f as bs acc = acc.data ++ List.zipWith f as bs

Ranges and enumeration #

enumFrom #

def List.enumFromTR {α : Type u_1} (n : Nat) (l : List α) :

List (Nat × α)

Tail recursive version of List.enumFrom.

Equations

One or more equations did not get rendered due to their size.

Instances For

@[csimp]

theorem List.enumFrom_eq_enumFromTR :

@List.enumFrom = @List.enumFromTR

theorem List.enumFrom_eq_enumFromTR.go (α : Type u_1) (l : List α) (n : Nat) :

let f := fun (a : α) (x : Nat × List (Nat × α)) => match x with | (n, acc) => (n - 1, (n - 1, a) :: acc); List.foldr f (n + l.length, []) l = (n, List.enumFrom n l)

Other list operations #

intercalate #

def List.intercalateTR {α : Type u_1} (sep : List α) :

List (List α) → List α

Tail recursive version of List.intercalate.

Equations

sep.intercalateTR [] = []
sep.intercalateTR [x_1] = x_1
sep.intercalateTR (x_1 :: xs) = List.intercalateTR.go (List.toArray sep) x_1 xs #[]

Instances For

def List.intercalateTR.go {α : Type u_1} (sep : Array α) :

List α → List (List α) → Array α → List α

Auxiliary for intercalateTR: intercalateTR.go sep x xs acc = acc.toList ++ intercalate sep.toList (x::xs)

Equations

List.intercalateTR.go sep x✝ [] x = x.toListAppend x✝
List.intercalateTR.go sep x✝ (y :: xs) x = List.intercalateTR.go sep y xs (x ++ x✝ ++ sep)

Instances For

@[csimp]

theorem List.intercalate_eq_intercalateTR :

@List.intercalate = @List.intercalateTR

theorem List.intercalate_eq_intercalateTR.go (α : Type u_1) (sep : List α) {acc : Array α} {x : List α} (xs : List (List α)) :

List.intercalateTR.go (List.toArray sep) x xs acc = acc.data ++ (List.intersperse sep (x :: xs)).join