Definitions on lists #
This file contains various definitions on lists. It does not contain
proofs about these definitions, those are contained in other files in Data.List
Equations
- List.instSDiffOfDecidableEq_mathlib = { sdiff := List.diff }
"Inhabited" take
function: Take n
elements from a list l
. If l
has less than n
elements, append n - length l
elements default
.
Equations
- List.takeI n l = List.takeD n l default
Instances For
findM tac l
returns the first element of l
on which tac
succeeds, and
fails otherwise.
Equations
- List.findM tac = List.firstM fun (a : α) => tac a $> a
Instances For
findM? p l
returns the first element a
of l
for which p a
returns
true. findM?
short-circuits, so p
is not necessarily run on every a
in
l
. This is a monadic version of List.find
.
Equations
- List.findM?' p [] = pure none
- List.findM?' p (a :: tail) = do let __discr ← p a match __discr with | { down := px } => if px = true then pure (some a) else List.findM?' p tail
Instances For
Monadic variant of foldlIdx
.
Equations
- List.foldlIdxM f b as = List.foldlIdx (fun (i : ℕ) (ma : m β) (b : α) => do let a ← ma f i a b) (pure b) as
Instances For
Monadic variant of foldrIdx
.
Equations
- List.foldrIdxM f b as = List.foldrIdx (fun (i : ℕ) (a : α) (mb : m β) => do let b ← mb f i a b) (pure b) as
Instances For
Auxiliary definition for mapIdxM'
.
Equations
- List.mapIdxMAux' f x [] = pure PUnit.unit
- List.mapIdxMAux' f x (a :: as) = f x a *> List.mapIdxMAux' f (x + 1) as
Instances For
A variant of mapIdxM
specialised to applicative actions which
return Unit
.
Equations
- List.mapIdxM' f as = List.mapIdxMAux' f 0 as
Instances For
l.Forall p
is equivalent to ∀ a ∈ l, p a
, but unfolds directly to a conjunction, i.e.
List.Forall p [0, 1, 2] = p 0 ∧ p 1 ∧ p 2
.
Equations
- List.Forall p [] = True
- List.Forall p [x_1] = p x_1
- List.Forall p (x_1 :: l) = (p x_1 ∧ List.Forall p l)
Instances For
An auxiliary function for defining permutations
. permutationsAux2 t ts r ys f
is equal to
(ys ++ ts, (insert_left ys t ts).map f ++ r)
, where insert_left ys t ts
(not explicitly
defined) is the list of lists of the form insert_nth n t (ys ++ ts)
for 0 ≤ n < length ys
.
permutations_aux2 10 [4, 5, 6] [] [1, 2, 3] id =
([1, 2, 3, 4, 5, 6],
[[10, 1, 2, 3, 4, 5, 6],
[1, 10, 2, 3, 4, 5, 6],
[1, 2, 10, 3, 4, 5, 6]])
Equations
- List.permutationsAux2 t ts r [] x = (ts, r)
- List.permutationsAux2 t ts r (y :: ys) x = match List.permutationsAux2 t ts r ys fun (x_1 : List α) => x (y :: x_1) with | (us, zs) => (y :: us, x (t :: y :: us) :: zs)
Instances For
A recursor for pairs of lists. To have C l₁ l₂
for all l₁
, l₂
, it suffices to have it for
l₂ = []
and to be able to pour the elements of l₁
into l₂
.
Equations
- List.permutationsAux.rec H0 H1 [] x = H0 x
- List.permutationsAux.rec H0 H1 (t :: ts) x = H1 t ts x (List.permutationsAux.rec H0 H1 ts (t :: x)) (List.permutationsAux.rec H0 H1 x [])
Instances For
An auxiliary function for defining permutations
. permutationsAux ts is
is the set of all
permutations of is ++ ts
that do not fix ts
.
Equations
- One or more equations did not get rendered due to their size.
Instances For
permutations'Aux t ts
inserts t
into every position in ts
, including the last.
This function is intended for use in specifications, so it is simpler than permutationsAux2
,
which plays roughly the same role in permutations
.
Note that (permutationsAux2 t [] [] ts id).2
is similar to this function, but skips the last
position:
permutations'Aux 10 [1, 2, 3] =
[[10, 1, 2, 3], [1, 10, 2, 3], [1, 2, 10, 3], [1, 2, 3, 10]]
(permutationsAux2 10 [] [] [1, 2, 3] id).2 =
[[10, 1, 2, 3], [1, 10, 2, 3], [1, 2, 10, 3]]
Equations
- List.permutations'Aux t [] = [[t]]
- List.permutations'Aux t (a :: tail) = (t :: a :: tail) :: List.map (List.cons a) (List.permutations'Aux t tail)
Instances For
List of all permutations of l
. This version of permutations
is less efficient but has
simpler definitional equations. The permutations are in a different order,
but are equal up to permutation, as shown by List.permutations_perm_permutations'
.
permutations [1, 2, 3] =
[[1, 2, 3], [2, 1, 3], [2, 3, 1],
[1, 3, 2], [3, 1, 2], [3, 2, 1]]
Equations
- [].permutations' = [[]]
- (a :: tail).permutations' = tail.permutations'.flatMap (List.permutations'Aux a)
Instances For
extractp p l
returns a pair of an element a
of l
satisfying the predicate
p
, and l
, with a
removed. If there is no such element a
it returns (none, l)
.
Equations
- List.extractp p [] = (none, [])
- List.extractp p (a :: tail) = if p a then (some a, tail) else match List.extractp p tail with | (a', l') => (a', a :: l')
Instances For
Equations
- One or more equations did not get rendered due to their size.
Equations
- One or more equations did not get rendered due to their size.
dedup l
removes duplicates from l
(taking only the last occurrence).
Defined as pwFilter (≠)
.
dedup [1, 0, 2, 2, 1] = [0, 2, 1]
Equations
- List.dedup = List.pwFilter fun (x1 x2 : α) => x1 ≠ x2
Instances For
Greedily create a sublist of a :: l
such that, for every two adjacent elements a, b
,
R a b
holds. Mostly used with ≠; for example, destutter' (≠) 1 [2, 2, 1, 1] = [1, 2, 1]
,
destutter' (≠) 1, [2, 3, 3] = [1, 2, 3]
, destutter' (<) 1 [2, 5, 2, 3, 4, 9] = [1, 2, 5, 9]
.
Equations
- List.destutter' R x [] = [x]
- List.destutter' R x (h :: l) = if R x h then x :: List.destutter' R h l else List.destutter' R x l
Instances For
Greedily create a sublist of l
such that, for every two adjacent elements a, b ∈ l
,
R a b
holds. Mostly used with ≠; for example, destutter (≠) [1, 2, 2, 1, 1] = [1, 2, 1]
,
destutter (≠) [1, 2, 3, 3] = [1, 2, 3]
, destutter (<) [1, 2, 5, 2, 3, 4, 9] = [1, 2, 5, 9]
.
Equations
- List.destutter R (h :: l) = List.destutter' R h l
- List.destutter R [] = []
Instances For
Given a decidable predicate p
and a proof of existence of a ∈ l
such that p a
,
choose the first element with this property. This version returns both a
and proofs
of a ∈ l
and p a
.
Equations
- List.chooseX p [] hp = ⋯.elim
- List.chooseX p (l :: ls) hp = if pl : p l then ⟨l, ⋯⟩ else match List.chooseX p ls ⋯ with | ⟨a, ha⟩ => ⟨a, ⋯⟩
Instances For
Given a decidable predicate p
and a proof of existence of a ∈ l
such that p a
,
choose the first element with this property. This version returns a : α
, and properties
are given by choose_mem
and choose_property
.
Equations
- List.choose p l hp = (List.chooseX p l hp).val
Instances For
mapDiagM' f l
calls f
on all elements in the upper triangular part of l × l
.
That is, for each e ∈ l
, it will run f e e
and then f e e'
for each e'
that appears after e
in l
.
Example: suppose l = [1, 2, 3]
. mapDiagM' f l
will evaluate, in this order,
f 1 1
, f 1 2
, f 1 3
, f 2 2
, f 2 3
, f 3 3
.
Equations
- List.mapDiagM' f [] = pure ()
- List.mapDiagM' f (a :: tail) = do let __discr ← f a a let x : Unit := __discr let __discr ← List.mapM' (f a) tail let x : List Unit := __discr List.mapDiagM' f tail
Instances For
Left-biased version of List.map₂
. map₂Left' f as bs
applies f
to each
pair of elements aᵢ ∈ as
and bᵢ ∈ bs
. If bs
is shorter than as
, f
is
applied to none
for the remaining aᵢ
. Returns the results of the f
applications and the remaining bs
.
map₂Left' prod.mk [1, 2] ['a'] = ([(1, some 'a'), (2, none)], [])
map₂Left' prod.mk [1] ['a', 'b'] = ([(1, some 'a')], ['b'])
Equations
- List.map₂Left' f [] x = ([], x)
- List.map₂Left' f (a :: as) [] = (List.map (fun (a : α) => f a none) (a :: as), [])
- List.map₂Left' f (a :: as) (b :: bs) = (f a (some b) :: (List.map₂Left' f as bs).fst, (List.map₂Left' f as bs).snd)
Instances For
Right-biased version of List.map₂
. map₂Right' f as bs
applies f
to each
pair of elements aᵢ ∈ as
and bᵢ ∈ bs
. If as
is shorter than bs
, f
is
applied to none
for the remaining bᵢ
. Returns the results of the f
applications and the remaining as
.
map₂Right' prod.mk [1] ['a', 'b'] = ([(some 1, 'a'), (none, 'b')], [])
map₂Right' prod.mk [1, 2] ['a'] = ([(some 1, 'a')], [2])
Equations
- List.map₂Right' f as bs = List.map₂Left' (flip f) bs as
Instances For
Left-biased version of List.map₂
. map₂Left f as bs
applies f
to each pair
aᵢ ∈ as
and bᵢ ∈ bs
. If bs
is shorter than as
, f
is applied to none
for the remaining aᵢ
.
map₂Left Prod.mk [1, 2] ['a'] = [(1, some 'a'), (2, none)]
map₂Left Prod.mk [1] ['a', 'b'] = [(1, some 'a')]
map₂Left f as bs = (map₂Left' f as bs).fst
Equations
- List.map₂Left f [] x = []
- List.map₂Left f (a :: as) [] = List.map (fun (a : α) => f a none) (a :: as)
- List.map₂Left f (a :: as) (b :: bs) = f a (some b) :: List.map₂Left f as bs
Instances For
Right-biased version of List.map₂
. map₂Right f as bs
applies f
to each
pair aᵢ ∈ as
and bᵢ ∈ bs
. If as
is shorter than bs
, f
is applied to
none
for the remaining bᵢ
.
map₂Right Prod.mk [1, 2] ['a'] = [(some 1, 'a')]
map₂Right Prod.mk [1] ['a', 'b'] = [(some 1, 'a'), (none, 'b')]
map₂Right f as bs = (map₂Right' f as bs).fst
Equations
- List.map₂Right f as bs = List.map₂Left (flip f) bs as
Instances For
Asynchronous version of List.map
.
Equations
- List.mapAsyncChunked f xs chunk_size = (List.map (fun (xs : List α) => Task.spawn fun (x : Unit) => List.map f xs) (List.toChunks chunk_size xs)).flatMap Task.get
Instances For
We add some n-ary versions of List.zipWith
for functions with more than two arguments.
These can also be written in terms of List.zip
or List.zipWith
.
For example, zipWith3 f xs ys zs
could also be written as
zipWith id (zipWith f xs ys) zs
or as
(zip xs <| zip ys zs).map <| fun ⟨x, y, z⟩ ↦ f x y z
.
Ternary version of List.zipWith
.
Equations
- List.zipWith3 f (x_3 :: xs) (y :: ys) (z :: zs) = f x_3 y z :: List.zipWith3 f xs ys zs
- List.zipWith3 f x✝¹ x✝ x = []
Instances For
Quaternary version of list.zipWith
.
Equations
- List.zipWith4 f (x_4 :: xs) (y :: ys) (z :: zs) (u :: us) = f x_4 y z u :: List.zipWith4 f xs ys zs us
- List.zipWith4 f x✝² x✝¹ x✝ x = []
Instances For
Quinary version of list.zipWith
.
Equations
- List.zipWith5 f (x_5 :: xs) (y :: ys) (z :: zs) (u :: us) (v :: vs) = f x_5 y z u v :: List.zipWith5 f xs ys zs us vs
- List.zipWith5 f x✝³ x✝² x✝¹ x✝ x = []
Instances For
Given a starting list old
, a list of booleans and a replacement list new
,
read the items in old
in succession and either replace them with the next element of new
or
not, according as to whether the corresponding boolean is true
or false
.
Equations
Instances For
iterate f a n
is [a, f a, ..., f^[n - 1] a]
.
Equations
- List.iterate f a 0 = []
- List.iterate f a n.succ = a :: List.iterate f (f a) n
Instances For
Tail-recursive version of List.iterate
.
Equations
- List.iterateTR f a n = List.iterateTR.loop f a n []
Instances For
iterateTR.loop f a n l := iterate f a n ++ reverse l
.
Equations
- List.iterateTR.loop f a 0 l = l.reverse
- List.iterateTR.loop f a n_1.succ l = List.iterateTR.loop f (f a) n_1 (a :: l)
Instances For
Runs a function over a list returning the intermediate results and a final result.
Equations
- List.mapAccumr f [] x = (x, [])
- List.mapAccumr f (y :: yr) x = ((f y (List.mapAccumr f yr x).fst).fst, (f y (List.mapAccumr f yr x).fst).snd :: (List.mapAccumr f yr x).snd)
Instances For
Length of the list obtained by mapAccumr
.
Runs a function over two lists returning the intermediate results and a final result.
Equations
- List.mapAccumr₂ f [] x✝ x = (x, [])
- List.mapAccumr₂ f x✝ [] x = (x, [])
- List.mapAccumr₂ f (x_3 :: xr) (y :: yr) x = ((f x_3 y (List.mapAccumr₂ f xr yr x).fst).fst, (f x_3 y (List.mapAccumr₂ f xr yr x).fst).snd :: (List.mapAccumr₂ f xr yr x).snd)
Instances For
Length of a list obtained using mapAccumr₂
.
Alias of the forward direction of List.mem_cons
.
Alias of List.not_exists_mem_nil
.
Alias of List.Sublist.length_le
.