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Additionally, we now have bash options to make sure we will fail hard were this situation to arise once again.
1171 lines
40 KiB
Idris
1171 lines
40 KiB
Idris
module Data.List
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import public Control.Function
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import Data.Nat
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import Data.List1
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import Data.Fin
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import public Data.Zippable
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%default total
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||| Boolean check for whether the list is the empty list.
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public export
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isNil : List a -> Bool
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isNil [] = True
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isNil _ = False
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||| Boolean check for whether the list contains a cons (::) / is non-empty.
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public export
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isCons : List a -> Bool
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isCons [] = False
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isCons _ = True
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||| Add an element to the end of a list.
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||| O(n). See the `Data.SnocList` module if you need to perform `snoc` often.
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public export
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snoc : List a -> a -> List a
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snoc xs x = xs ++ [x]
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||| Take `n` first elements from `xs`, returning the whole list if
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||| `n` >= length `xs`.
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|||
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||| @ n the number of elements to take
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||| @ xs the list to take the elements from
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public export
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take : (n : Nat) -> (xs : List a) -> List a
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take (S k) (x :: xs) = x :: take k xs
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take _ _ = []
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||| Remove `n` first elements from `xs`, returning the empty list if
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||| `n >= length xs`
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||| @ n the number of elements to remove
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||| @ xs the list to drop the elements from
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public export
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drop : (n : Nat) -> (xs : List a) -> List a
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drop Z xs = xs
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drop (S n) [] = []
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drop (S n) (_::xs) = drop n xs
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||| Satisfiable if `k` is a valid index into `xs`.
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|||
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||| @ k the potential index
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||| @ xs the list into which k may be an index
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public export
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data InBounds : (k : Nat) -> (xs : List a) -> Type where
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||| Z is a valid index into any cons cell
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InFirst : InBounds Z (x :: xs)
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||| Valid indices can be extended
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InLater : InBounds k xs -> InBounds (S k) (x :: xs)
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public export
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Uninhabited (InBounds k []) where
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uninhabited InFirst impossible
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uninhabited (InLater _) impossible
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export
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Uninhabited (InBounds k xs) => Uninhabited (InBounds (S k) (x::xs)) where
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uninhabited (InLater y) = uninhabited y
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||| Decide whether `k` is a valid index into `xs`.
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public export
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inBounds : (k : Nat) -> (xs : List a) -> Dec (InBounds k xs)
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inBounds _ [] = No uninhabited
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inBounds Z (_ :: _) = Yes InFirst
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inBounds (S k) (x :: xs) with (inBounds k xs)
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inBounds (S k) (x :: xs) | (Yes prf) = Yes (InLater prf)
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inBounds (S k) (x :: xs) | (No contra)
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= No $ \(InLater y) => contra y
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||| Find a particular element of a list.
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|||
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||| @ ok a proof that the index is within bounds
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public export
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index : (n : Nat) -> (xs : List a) -> {auto 0 ok : InBounds n xs} -> a
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index Z (x :: xs) {ok = InFirst} = x
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index (S k) (_ :: xs) {ok = InLater _} = index k xs
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public export
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index' : (xs : List a) -> Fin (length xs) -> a
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index' (x::_) FZ = x
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index' (_::xs) (FS i) = index' xs i
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||| Generate a list by repeatedly applying a partial function until exhausted.
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||| @ f the function to iterate
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||| @ x the initial value that will be the head of the list
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covering
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public export
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iterate : (f : a -> Maybe a) -> (x : a) -> List a
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iterate f x = x :: case f x of
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Nothing => []
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Just y => iterate f y
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||| Given a function `f` which extracts an element of `b` and `b`'s
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||| continuation, return the list consisting of the extracted elements.
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||| CAUTION: Only terminates if `f` eventually returns `Nothing`.
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|||
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||| @ f a function which provides an element of `b` and the rest of `b`
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||| @ b a structure contanining any number of elements
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covering
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public export
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unfoldr : (f : b -> Maybe (a, b)) -> b -> List a
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unfoldr f c = case f c of
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Nothing => []
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Just (a, n) => a :: unfoldr f n
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||| Returns the list of elements obtained by applying `f` to `x` `0` to `n-1` times,
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||| starting with `x`.
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|||
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||| @ n the number of times to iterate `f` over `x`
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||| @ f a function producing a series
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||| @ x the initial element of the series
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public export
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iterateN : (n : Nat) -> (f : a -> a) -> (x : a) -> List a
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iterateN Z _ _ = []
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iterateN (S k) f x = x :: iterateN k f (f x)
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||| Get the longest prefix of the list that satisfies the predicate.
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|||
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||| @ p a custom predicate for the elements of the list
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||| @ xs the list of elements
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public export
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takeWhile : (p : a -> Bool) -> (xs : List a) -> List a
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takeWhile p [] = []
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takeWhile p (x::xs) = if p x then x :: takeWhile p xs else []
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||| Remove elements from the list until an element no longer satisfies the
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||| predicate.
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|||
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||| @ p a custom predicate for the elements of the list
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||| @ xs the list of elements to remove from
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public export
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dropWhile : (p : a -> Bool) -> (xs : List a) -> List a
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dropWhile p [] = []
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dropWhile p (x::xs) = if p x then dropWhile p xs else x::xs
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||| Find the first element of the list that satisfies the predicate.
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public export
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find : (p : a -> Bool) -> (xs : List a) -> Maybe a
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find p [] = Nothing
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find p (x::xs) = if p x then Just x else find p xs
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||| Find the index and proof of InBounds of the first element (if exists) of a
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||| list that satisfies the given test, else `Nothing`.
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public export
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findIndex : (a -> Bool) -> (xs : List a) -> Maybe $ Fin (length xs)
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findIndex _ [] = Nothing
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findIndex p (x :: xs) = if p x
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then Just FZ
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else FS <$> findIndex p xs
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||| Find indices of all elements that satisfy the given test.
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public export
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findIndices : (a -> Bool) -> List a -> List Nat
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findIndices p = h 0 where
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h : Nat -> List a -> List Nat
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h _ [] = []
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h lvl (x :: xs) = if p x
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then lvl :: h (S lvl) xs
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else h (S lvl) xs
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||| Find associated information in a list using a custom comparison.
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public export
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lookupBy : (a -> b -> Bool) -> a -> List (b, v) -> Maybe v
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lookupBy p e [] = Nothing
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lookupBy p e ((l, r) :: xs) =
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if p e l then
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Just r
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else
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lookupBy p e xs
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||| Find associated information in a list using Boolean equality.
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public export
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lookup : Eq a => a -> List (a, b) -> Maybe b
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lookup = lookupBy (==)
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||| Remove duplicate elements from a list using a custom comparison. The general
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||| case of `nub`.
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||| O(n^2).
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|||
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||| @ p a custom comparison for detecting duplicate elements
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||| @ xs the list to remove the duplicates from
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public export
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nubBy : (p : a -> a -> Bool) -> (xs : List a) -> List a
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nubBy = nubBy' []
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where
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nubBy' : List a -> (a -> a -> Bool) -> List a -> List a
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nubBy' acc p [] = []
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nubBy' acc p (x::xs) =
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if elemBy p x acc then
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nubBy' acc p xs
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else
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x :: nubBy' (x::acc) p xs
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||| The nub function removes duplicate elements from a list using
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||| boolean equality. In particular, it keeps only the first occurrence of each
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||| element. It is a special case of `nubBy`, which allows the programmer to
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||| supply their own equality test.
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||| O(n^2).
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|||
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||| ```idris example
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||| nub (the (List _) [1,2,1,3])
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||| ```
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public export
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nub : Eq a => List a -> List a
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nub = nubBy (==)
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||| Insert an element at a particular index.
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|||
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||| ```idris example
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||| insertAt 1 [6, 8, 9] 7
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||| ```
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||| @idx The index of the inserted value in the resulting list.
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||| @x The value to insert.
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||| @xs The list to insert the value into.
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public export
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insertAt : (idx : Nat) -> (x : a) -> (xs : List a) -> {auto 0 ok : idx `LTE` length xs} -> List a
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insertAt Z x xs = x :: xs
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insertAt {ok=LTESucc _} (S n) x (y :: ys) = y :: (insertAt n x ys)
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||| Construct a new list consisting of all but the indicated element.
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|||
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||| ```idris example
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||| deleteAt 3 [5, 6, 7, 8, 9]
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||| ```
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||| @ idx The index of the value to delete.
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||| @ xs The list to delete the value from.
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public export
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deleteAt : (idx : Nat) -> (xs : List a) -> {auto 0 prf : InBounds idx xs} -> List a
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deleteAt {prf=InFirst} Z (_ :: xs) = xs
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deleteAt {prf=InLater _} (S k) (x :: xs) = x :: deleteAt k xs
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||| The deleteBy function behaves like delete, but takes a user-supplied equality predicate.
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public export
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deleteBy : (a -> b -> Bool) -> a -> List b -> List b
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deleteBy _ _ [] = []
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deleteBy eq x (y::ys) = if x `eq` y then ys else y :: deleteBy eq x ys
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||| `delete x` removes the first occurrence of `x` from its list argument. For
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||| example,
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|||
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|||````idris example
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|||delete 'a' ['b', 'a', 'n', 'a', 'n', 'a']
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|||````
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||| It is a special case of deleteBy, which allows the programmer to supply
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||| their own equality test.
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public export
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delete : Eq a => a -> List a -> List a
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delete = deleteBy (==)
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||| Delete the first occurrence of each element from the second list in the first
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||| list where equality is determined by the predicate passed as the first argument.
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||| @ p A function that returns true when its two arguments should be considered equal.
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||| @ source The list to delete elements from.
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||| @ undesirables The list of elements to delete.
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public export
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deleteFirstsBy : (p : a -> b -> Bool) -> (source : List b) -> (undesirables : List a) -> List b
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deleteFirstsBy p = foldl (flip (deleteBy p))
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infix 7 \\
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||| The non-associative list-difference.
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||| A specialized form of @deleteFirstsBy@ where the predicate is equality under the @Eq@
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||| interface.
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||| Deletes the first occurrence of each element of the second list from the first list.
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||| In the following example, the result is `[2, 4]`.
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||| ```idris example
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||| [1, 2, 3, 4] \\ [1, 3]
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||| ```
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|||
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public export
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(\\) : Eq a => List a -> List a -> List a
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(\\) = foldl (flip delete)
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||| The unionBy function returns the union of two lists by user-supplied equality predicate.
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public export
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unionBy : (a -> a -> Bool) -> List a -> List a -> List a
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unionBy eq xs ys = xs ++ foldl (flip (deleteBy eq)) (nubBy eq ys) xs
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||| Compute the union of two lists according to their `Eq` implementation.
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||| ```idris example
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||| union ['d', 'o', 'g'] ['c', 'o', 'w']
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||| ```
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public export
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union : Eq a => List a -> List a -> List a
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union = unionBy (==)
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||| Like @span@ but using a predicate that might convert a to b, i.e. given a
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||| predicate from a to Maybe b and a list of as, returns a tuple consisting of
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||| the longest prefix of the list where a -> Just b, and the rest of the list.
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public export
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spanBy : (a -> Maybe b) -> List a -> (List b, List a)
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spanBy p [] = ([], [])
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spanBy p (x :: xs) = case p x of
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Nothing => ([], x :: xs)
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Just y => let (ys, zs) = spanBy p xs in (y :: ys, zs)
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||| Given a predicate and a list, returns a tuple consisting of the longest
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||| prefix of the list whose elements satisfy the predicate, and the rest of the
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||| list.
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public export
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span : (a -> Bool) -> List a -> (List a, List a)
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span p [] = ([], [])
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span p (x::xs) =
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if p x then
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let (ys, zs) = span p xs in
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(x::ys, zs)
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else
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([], x::xs)
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||| Similar to `span` but negates the predicate, i.e.: returns a tuple
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||| consisting of the longest prefix of the list whose elements don't satisfy
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||| the predicate, and the rest of the list.
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public export
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break : (a -> Bool) -> List a -> (List a, List a)
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break p xs = span (not . p) xs
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public export
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singleton : a -> List a
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singleton x = [x]
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public export
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split : (a -> Bool) -> List a -> List1 (List a)
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split p xs =
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case break p xs of
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(chunk, []) => singleton chunk
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(chunk, (c :: rest)) => chunk ::: forget (split p (assert_smaller xs rest))
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||| Split the list `xs` at the index `n`. If `n > length xs`, returns a tuple
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||| consisting of `xs` and `[]`.
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|||
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||| @ n the index to split the list at
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||| @ xs the list to split
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public export
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splitAt : (n : Nat) -> (xs : List a) -> (List a, List a)
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splitAt Z xs = ([], xs)
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splitAt (S k) [] = ([], [])
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splitAt (S k) (x :: xs)
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= let (tk, dr) = splitAt k xs in
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(x :: tk, dr)
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||| Divide the list into a tuple containing two smaller lists: one with the
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||| elements that satisfies the given predicate and another with the elements
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||| that don't.
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|||
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||| @ p the predicate to partition according to
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||| @ xs the list to partition
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public export
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partition : (p : a -> Bool) -> (xs : List a) -> (List a, List a)
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partition p [] = ([], [])
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partition p (x::xs) =
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let (lefts, rights) = partition p xs in
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if p x then
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(x::lefts, rights)
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else
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(lefts, x::rights)
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||| The inits function returns all initial segments of the argument, shortest
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||| first. For example,
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|||
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||| ```idris example
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||| inits [1,2,3]
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||| ```
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public export
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inits : List a -> List (List a)
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inits xs = [] :: case xs of
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[] => []
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x :: xs' => map (x ::) (inits xs')
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||| The tails function returns all final segments of the argument, longest
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||| first. For example,
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|||
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||| ```idris example
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||| tails [1,2,3] == [[1,2,3], [2,3], [3], []]
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|||```
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public export
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tails : List a -> List (List a)
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tails xs = xs :: case xs of
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[] => []
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_ :: xs' => tails xs'
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||| Split on the given element.
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|||
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||| ```idris example
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||| splitOn 0 [1,0,2,0,0,3]
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||| ```
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|||
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public export
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splitOn : Eq a => a -> List a -> List1 (List a)
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splitOn a = split (== a)
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|
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||| Replace an element at a particlar index with another.
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|||
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||| ```idris example
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||| replaceAt 2 6 [1, 2, 3, 4]
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||| ```
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|||
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||| @idx The index of the value to replace.
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||| @x The value to insert.
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||| @xs The list in which to replace an element.
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public export
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replaceAt : (idx : Nat) -> a -> (xs : List a) -> {auto 0 ok : InBounds idx xs} -> List a
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replaceAt Z y (_ :: xs) {ok=InFirst} = y :: xs
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replaceAt (S k) y (x :: xs) {ok=InLater _} = x :: replaceAt k y xs
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||| Replace the elements in the list that satisfy the predicate with the given
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||| value. The general case of `replaceOn`.
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|||
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||| @ p the predicate to replace elements in the list according to
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||| @ b the element to replace with
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||| @ l the list to perform the replacements on
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public export
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replaceWhen : (p : a -> Bool) -> (b : a) -> (l : List a) -> List a
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replaceWhen p b l = map (\c => if p c then b else c) l
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||| Replace the elements in the list that are equal to `e`, using boolean
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||| equality, with `b`. A special case of `replaceWhen`, using `== e` as the
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||| predicate.
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|||
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||| ```idris example
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||| > replaceOn '-' ',' ['1', '-', '2', '-', '3']
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||| ['1', ',', '2', ',', '3']
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||| ```
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|||
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||| @ e the element to find and replace
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||| @ b the element to replace with
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||| @ l the list to perform the replacements on
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public export
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replaceOn : Eq a => (e : a) -> (b : a) -> (l : List a) -> List a
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replaceOn e = replaceWhen (== e)
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replicateTR : List a -> Nat -> a -> List a
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replicateTR as Z _ = as
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replicateTR as (S n) x = replicateTR (x :: as) n x
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|
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||| Construct a list with `n` copies of `x`.
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|||
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||| @ n how many copies
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||| @ x the element to replicate
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public export
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replicate : (n : Nat) -> (x : a) -> List a
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replicate Z _ = []
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replicate (S n) x = x :: replicate n x
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|
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-- Data.List.replicateTRIsReplicate proves these are equivalent.
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%transform "tailRecReplicate" List.replicate = List.replicateTR Nil
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|
|
|
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||| Compute the intersect of two lists by user-supplied equality predicate.
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export
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intersectBy : (a -> a -> Bool) -> List a -> List a -> List a
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intersectBy eq xs ys = [x | x <- xs, any (eq x) ys]
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|
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||| Compute the intersection of two lists according to the `Eq` implementation for
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||| the elements.
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export
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intersect : Eq a => List a -> List a -> List a
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intersect = intersectBy (==)
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|
|
|
||| Compute the intersect of all the lists in the given list of lists, according
|
|
||| to the user-supplied equality predicate.
|
|
|||
|
|
||| @ eq the predicate for computing the intersection
|
|
||| @ ls the list of lists to compute the intersect of
|
|
export
|
|
intersectAllBy : (eq : a -> a -> Bool) -> (ls : List (List a)) -> List a
|
|
intersectAllBy eq [] = []
|
|
intersectAllBy eq (xs :: xss) = filter (\x => all (elemBy eq x) xss) xs
|
|
|
|
||| Compute the intersect of all the lists in the given list of lists, according
|
|
||| to boolean equality. A special case of `intersectAllBy`, using `==` as the
|
|
||| equality predicate.
|
|
|||
|
|
||| @ ls the list of lists to compute the intersect of
|
|
export
|
|
intersectAll : Eq a => (ls : List (List a)) -> List a
|
|
intersectAll = intersectAllBy (==)
|
|
|
|
---------------------------
|
|
-- Zippable --
|
|
---------------------------
|
|
|
|
public export
|
|
Zippable List where
|
|
zipWith _ [] _ = []
|
|
zipWith _ _ [] = []
|
|
zipWith f (x :: xs) (y :: ys) = f x y :: zipWith f xs ys
|
|
|
|
zipWith3 _ [] _ _ = []
|
|
zipWith3 _ _ [] _ = []
|
|
zipWith3 _ _ _ [] = []
|
|
zipWith3 f (x :: xs) (y :: ys) (z :: zs) = f x y z :: zipWith3 f xs ys zs
|
|
|
|
unzipWith f [] = ([], [])
|
|
unzipWith f (x :: xs) = let (b, c) = f x
|
|
(bs, cs) = unzipWith f xs in
|
|
(b :: bs, c :: cs)
|
|
|
|
unzipWith3 f [] = ([], [], [])
|
|
unzipWith3 f (x :: xs) = let (b, c, d) = f x
|
|
(bs, cs, ds) = unzipWith3 f xs in
|
|
(b :: bs, c :: cs, d :: ds)
|
|
|
|
---------------------------
|
|
-- Non-empty List
|
|
---------------------------
|
|
|
|
||| Proof that a given list is non-empty.
|
|
public export
|
|
data NonEmpty : (xs : List a) -> Type where
|
|
IsNonEmpty : NonEmpty (x :: xs)
|
|
|
|
-- The empty list (Nil) cannot be `NonEmpty`.
|
|
export
|
|
Uninhabited (NonEmpty []) where
|
|
uninhabited IsNonEmpty impossible
|
|
|
|
||| Get the head of a non-empty list.
|
|
||| @ ok proof the list is non-empty
|
|
public export
|
|
head : (l : List a) -> {auto 0 ok : NonEmpty l} -> a
|
|
head [] impossible
|
|
head (x :: _) = x
|
|
|
|
||| Get the tail of a non-empty list.
|
|
||| @ ok proof the list is non-empty
|
|
public export
|
|
tail : (l : List a) -> {auto 0 ok : NonEmpty l} -> List a
|
|
tail [] impossible
|
|
tail (_ :: xs) = xs
|
|
|
|
||| Retrieve the last element of a non-empty list.
|
|
||| @ ok proof that the list is non-empty
|
|
public export
|
|
last : (l : List a) -> {auto 0 ok : NonEmpty l} -> a
|
|
last [] impossible
|
|
last [x] = x
|
|
last (x :: xs@(_::_)) = last xs
|
|
|
|
||| Return all but the last element of a non-empty list.
|
|
||| @ ok proof the list is non-empty
|
|
public export
|
|
init : (l : List a) -> {auto 0 ok : NonEmpty l} -> List a
|
|
init [] impossible
|
|
init [x] = []
|
|
init (x :: xs@(_::_)) = x :: init xs
|
|
|
|
||| Computes the minimum of a non-empty list
|
|
public export
|
|
minimum : Ord a => (xs : List a) -> {auto 0 _ : NonEmpty xs} -> a
|
|
minimum (x :: xs) = foldl min x xs
|
|
|
|
||| Attempt to deconstruct the list into a head and a tail.
|
|
public export
|
|
uncons' : List a -> Maybe (a, List a)
|
|
uncons' [] = Nothing
|
|
uncons' (x :: xs) = Just (x, xs)
|
|
|
|
||| Attempt to get the head of a list. If the list is empty, return `Nothing`.
|
|
public export
|
|
head' : List a -> Maybe a
|
|
head' = map fst . uncons'
|
|
|
|
||| Attempt to get the tail of a list. If the list is empty, return `Nothing`.
|
|
export
|
|
tail' : List a -> Maybe (List a)
|
|
tail' = map snd . uncons'
|
|
|
|
||| Attempt to retrieve the last element of a non-empty list.
|
|
|||
|
|
||| If the list is empty, return `Nothing`.
|
|
export
|
|
last' : List a -> Maybe a
|
|
last' [] = Nothing
|
|
last' xs@(_::_) = Just (last xs)
|
|
|
|
||| Attempt to return all but the last element of a non-empty list.
|
|
|||
|
|
||| If the list is empty, return `Nothing`.
|
|
export
|
|
init' : List a -> Maybe (List a)
|
|
init' [] = Nothing
|
|
init' xs@(_::_) = Just (init xs)
|
|
|
|
||| Foldr a non-empty list, using `map` to transform the first accumulated
|
|
||| element to something of the desired type and `func` to accumulate the
|
|
||| elements.
|
|
|||
|
|
||| @ func the function used to accumulate the elements
|
|
||| @ map an initial transformation from the element to the accumulated type
|
|
||| @ l the non-empty list to foldr
|
|
||| @ ok proof that the list is non-empty
|
|
public export
|
|
foldr1By : (func : a -> b -> b) -> (map : a -> b) ->
|
|
(l : List a) -> {auto 0 ok : NonEmpty l} -> b
|
|
foldr1By f map [] impossible
|
|
foldr1By f map [x] = map x
|
|
foldr1By f map (x :: xs@(_::_)) = f x (foldr1By f map xs)
|
|
|
|
||| Foldl a non-empty list, using `map` to transform the first accumulated
|
|
||| element to something of the desired type and `func` to accumulate the
|
|
||| elements.
|
|
|||
|
|
||| @ func the function used to accumulate the elements
|
|
||| @ map an initial transformation from the element to the accumulated type
|
|
||| @ l the non-empty list to foldl
|
|
||| @ ok proof that the list is non-empty
|
|
public export
|
|
foldl1By : (func : b -> a -> b) -> (map : a -> b) ->
|
|
(l : List a) -> {auto 0 ok : NonEmpty l} -> b
|
|
foldl1By f map [] impossible
|
|
foldl1By f map (x::xs) = foldl f (map x) xs
|
|
|
|
||| Foldr a non-empty list without seeding the accumulator.
|
|
|||
|
|
||| @ ok proof that the list is non-empty
|
|
public export
|
|
foldr1 : (a -> a -> a) -> (l : List a) -> {auto 0 ok : NonEmpty l} -> a
|
|
foldr1 f xs = foldr1By f id xs
|
|
|
|
||| Foldl a non-empty list without seeding the accumulator.
|
|
|||
|
|
||| @ ok proof that the list is non-empty
|
|
public export
|
|
foldl1 : (a -> a -> a) -> (l : List a) -> {auto 0 ok : NonEmpty l} -> a
|
|
foldl1 f xs = foldl1By f id xs
|
|
|
|
||| Convert to a non-empty list.
|
|
|||
|
|
||| @ ok proof the list is non-empty
|
|
export
|
|
toList1 : (l : List a) -> {auto 0 ok : NonEmpty l} -> List1 a
|
|
toList1 [] impossible
|
|
toList1 (x :: xs) = x ::: xs
|
|
|
|
||| Convert to a non-empty list, returning Nothing if the list is empty.
|
|
public export
|
|
toList1' : (l : List a) -> Maybe (List1 a)
|
|
toList1' [] = Nothing
|
|
toList1' (x :: xs) = Just (x ::: xs)
|
|
|
|
||| Interleave two lists.
|
|
||| ```idris example
|
|
||| > interleave ["a", "c", "e"] ["b", "d", "f"]
|
|
||| ["a", "b", "c", "d", "e", "f"]
|
|
||| ```
|
|
public export
|
|
interleave : (xs, ys : List a) -> List a
|
|
interleave [] ys = ys
|
|
interleave (x :: xs) ys = x :: interleave ys xs
|
|
|
|
||| Prefix every element in the list with the given element.
|
|
|||
|
|
||| @ sep the value to prefix
|
|
||| @ xs the list of elements to prefix with the given element
|
|
|||
|
|
||| ```idris example
|
|
||| > with List (mergeReplicate '>' ['a', 'b', 'c', 'd', 'e'])
|
|
||| ['>', 'a', '>', 'b', '>', 'c', '>', 'd', '>', 'e']
|
|
||| ```
|
|
public export
|
|
mergeReplicate : (sep : a) -> (xs : List a) -> List a
|
|
mergeReplicate sep [] = []
|
|
mergeReplicate sep (y::ys) = sep :: y :: mergeReplicate sep ys
|
|
|
|
||| Insert some separator between the elements of a list.
|
|
|||
|
|
||| @ sep the value to intersperse
|
|
||| @ xs the list of elements to intersperse with the separator
|
|
|||
|
|
||| ```idris example
|
|
||| > with List (intersperse ',' ['a', 'b', 'c', 'd', 'e'])
|
|
||| ['a', ',', 'b', ',', 'c', ',', 'd', ',', 'e']
|
|
||| ```
|
|
public export
|
|
intersperse : (sep : a) -> (xs : List a) -> List a
|
|
intersperse sep [] = []
|
|
intersperse sep (x::xs) = x :: mergeReplicate sep xs
|
|
|
|
||| Given a separator list and some more lists, produce a new list by
|
|
||| placing the separator between each of the lists.
|
|
|||
|
|
||| @ sep the separator
|
|
||| @ xss the lists between which the separator will be placed
|
|
|||
|
|
||| ```idris example
|
|
||| intercalate [0, 0, 0] [ [1, 2, 3], [4, 5, 6], [7, 8, 9] ]
|
|
||| ```
|
|
export
|
|
intercalate : (sep : List a) -> (xss : List (List a)) -> List a
|
|
intercalate sep xss = concat $ intersperse sep xss
|
|
|
|
||| Extract all of the values contained in a List of Maybes
|
|
public export
|
|
catMaybes : List (Maybe a) -> List a
|
|
catMaybes = mapMaybe id
|
|
|
|
--------------------------------------------------------------------------------
|
|
-- Sorting
|
|
--------------------------------------------------------------------------------
|
|
|
|
||| Check whether a list is sorted with respect to the default ordering for the type of its elements.
|
|
export
|
|
sorted : Ord a => List a -> Bool
|
|
sorted (x :: xs @ (y :: _)) = x <= y && sorted xs
|
|
sorted _ = True
|
|
|
|
||| Merge two sorted lists using an arbitrary comparison
|
|
||| predicate. Note that the lists must have been sorted using this
|
|
||| predicate already.
|
|
export
|
|
mergeBy : (a -> a -> Ordering) -> List a -> List a -> List a
|
|
mergeBy order [] right = right
|
|
mergeBy order left [] = left
|
|
mergeBy order (x::xs) (y::ys) =
|
|
-- The code below will emit `y` before `x` whenever `x == y`.
|
|
-- If you change this, `sortBy` will stop being stable, unless you fix `sortBy`, too.
|
|
case order x y of
|
|
LT => x :: mergeBy order xs (y::ys)
|
|
_ => y :: mergeBy order (x::xs) ys
|
|
|
|
||| Merge two sorted lists using the default ordering for the type of their elements.
|
|
export
|
|
merge : Ord a => List a -> List a -> List a
|
|
merge left right = mergeBy compare left right
|
|
|
|
||| Sort a list using some arbitrary comparison predicate.
|
|
|||
|
|
||| @ cmp how to compare elements
|
|
||| @ xs the list to sort
|
|
export
|
|
sortBy : (cmp : a -> a -> Ordering) -> (xs : List a) -> List a
|
|
sortBy cmp [] = []
|
|
sortBy cmp [x] = [x]
|
|
sortBy cmp xs = let (x, y) = split xs in
|
|
mergeBy cmp
|
|
(sortBy cmp (assert_smaller xs x))
|
|
(sortBy cmp (assert_smaller xs y)) -- not structurally smaller, hence assert
|
|
where
|
|
splitRec : List b -> List a -> (List a -> List a) -> (List a, List a)
|
|
splitRec (_::_::xs) (y::ys) zs = splitRec xs ys (zs . ((::) y))
|
|
splitRec _ ys zs = (ys, zs [])
|
|
-- In the above base-case clause, we put `ys` on the LHS to get a stable sort.
|
|
-- This is because `mergeBy` prefers taking elements from its RHS operand
|
|
-- if both heads are equal, and all elements in `zs []` precede all elements of `ys`
|
|
-- in the original list.
|
|
|
|
split : List a -> (List a, List a)
|
|
split xs = splitRec xs xs id
|
|
|
|
||| Sort a list using the default ordering for the type of its elements.
|
|
export
|
|
sort : Ord a => List a -> List a
|
|
sort = sortBy compare
|
|
|
|
||| Check whether the `left` list is a prefix of the `right` one, according to
|
|
||| `match`. Returns the matched prefix together with the leftover suffix.
|
|
|||
|
|
||| @ match a custom matching function for checking the elements are convertible
|
|
||| @ left the list which might be a prefix of `right`
|
|
||| @ right the list of elements to compare against
|
|
public export
|
|
prefixOfBy : (match : a -> b -> Maybe m) ->
|
|
(left : List a) -> (right : List b) ->
|
|
Maybe (List m, List b)
|
|
prefixOfBy p = go [<] where
|
|
go : SnocList m -> List a -> List b -> Maybe (List m, List b)
|
|
go sm [] bs = pure (sm <>> [], bs)
|
|
go sm as [] = Nothing
|
|
go sm (a :: as) (b :: bs) = go (sm :< !(p a b)) as bs
|
|
|
|
||| Check whether the `left` list is a prefix of the `right` one, using the
|
|
||| provided equality function to compare elements.
|
|
|||
|
|
||| @ eq a custom equality function for comparing the elements
|
|
||| @ left the list which might be a prefix of `right`
|
|
||| @ right the list of elements to compare againts
|
|
public export
|
|
isPrefixOfBy : (eq : a -> b -> Bool) ->
|
|
(left : List a) -> (right : List b) -> Bool
|
|
isPrefixOfBy p [] _ = True
|
|
isPrefixOfBy p _ [] = False
|
|
isPrefixOfBy p (x::xs) (y::ys) = p x y && isPrefixOfBy p xs ys
|
|
|
|
||| The isPrefixOf function takes two lists and returns True iff the first list
|
|
||| is a prefix of the second when comparing elements using `==`.
|
|
public export
|
|
isPrefixOf : Eq a => List a -> List a -> Bool
|
|
isPrefixOf = isPrefixOfBy (==)
|
|
|
|
||| Check whether the `left` is a suffix of the `right` one, according to
|
|
||| `match`. Returns the matched suffix together with the leftover prefix.
|
|
|||
|
|
||| @ match a custom matching function for checking the elements are convertible
|
|
||| @ left the list which might be a prefix of `right`
|
|
||| @ right the list of elements to compare against
|
|
public export
|
|
suffixOfBy : (match : a -> b -> Maybe m) ->
|
|
(left : List a) -> (right : List b) ->
|
|
Maybe (List b, List m)
|
|
suffixOfBy match left right
|
|
= do (ms, bs) <- prefixOfBy match (reverse left) (reverse right)
|
|
pure (reverse bs, reverse ms)
|
|
|
|
||| Check whether the `left` is a suffix of the `right` one, using the provided
|
|
||| equality function to compare elements.
|
|
|||
|
|
||| @ eq a custom equality function for comparing the elements
|
|
||| @ left the list which might be a suffix of `right`
|
|
||| @ right the list of elements to compare againts
|
|
public export
|
|
isSuffixOfBy : (eq : a -> b -> Bool) ->
|
|
(left : List a) -> (right : List b) -> Bool
|
|
isSuffixOfBy p left right = isPrefixOfBy p (reverse left) (reverse right)
|
|
|
|
||| The isSuffixOf function takes two lists and returns True iff the first list
|
|
||| is a suffix of the second when comparing elements using `==`.
|
|
public export
|
|
isSuffixOf : Eq a => List a -> List a -> Bool
|
|
isSuffixOf = isSuffixOfBy (==)
|
|
|
|
||| Check whether the `left` list is an infix of the `right` one, according to
|
|
||| `match`. Returns the shortest unmatched prefix, matched infix and the leftover suffix.
|
|
public export
|
|
infixOfBy : (match : a -> b -> Maybe m) ->
|
|
(left : List a) -> (right : List b) ->
|
|
Maybe (List b, List m, List b)
|
|
infixOfBy _ [] right = Just ([], [], right)
|
|
infixOfBy p left@(_::_) right = go [<] right where
|
|
go : (acc : SnocList b) -> List b -> Maybe (List b, List m, List b)
|
|
go _ [] = Nothing
|
|
go pre curr@(c::rest) = case prefixOfBy p left curr of
|
|
Just (inf, post) => Just (pre <>> [], inf, post)
|
|
Nothing => go (pre:<c) rest
|
|
|
|
||| Check whether the `left` is an infix of the `right` one, using the provided
|
|
||| equality function to compare elements.
|
|
public export
|
|
isInfixOfBy : (eq : a -> b -> Bool) ->
|
|
(left : List a) -> (right : List b) -> Bool
|
|
isInfixOfBy p n h = any (isPrefixOfBy p n) (tails h)
|
|
|
|
||| The isInfixOf function takes two lists and returns True iff the first list
|
|
||| is contained, wholly and intact, anywhere within the second.
|
|
|||
|
|
||| ```idris example
|
|
||| isInfixOf ['b','c'] ['a', 'b', 'c', 'd']
|
|
||| ```
|
|
||| ```idris example
|
|
||| isInfixOf ['b','d'] ['a', 'b', 'c', 'd']
|
|
||| ```
|
|
|||
|
|
public export
|
|
isInfixOf : Eq a => List a -> List a -> Bool
|
|
isInfixOf = isInfixOfBy (==)
|
|
|
|
||| Transposes rows and columns of a list of lists.
|
|
|||
|
|
||| ```idris example
|
|
||| with List transpose [[1, 2], [3, 4]]
|
|
||| ```
|
|
|||
|
|
||| This also works for non square scenarios, thus
|
|
||| involution does not always hold:
|
|
|||
|
|
||| transpose [[], [1, 2]] = [[1], [2]]
|
|
||| transpose (transpose [[], [1, 2]]) = [[1, 2]]
|
|
export
|
|
transpose : List (List a) -> List (List a)
|
|
transpose [] = []
|
|
transpose (heads :: tails) = spreadHeads heads (transpose tails) where
|
|
spreadHeads : List a -> List (List a) -> List (List a)
|
|
spreadHeads [] tails = tails
|
|
spreadHeads (head :: heads) [] = [head] :: spreadHeads heads []
|
|
spreadHeads (head :: heads) (tail :: tails) = (head :: tail) :: spreadHeads heads tails
|
|
|
|
------------------------------------------------------------------------
|
|
-- Grouping
|
|
------------------------------------------------------------------------
|
|
|
|
||| `groupBy` operates like `group`, but uses the provided equality
|
|
||| predicate instead of `==`.
|
|
public export
|
|
groupBy : (a -> a -> Bool) -> List a -> List (List1 a)
|
|
groupBy _ [] = []
|
|
groupBy eq (h :: t) = let (ys,zs) = go h t
|
|
in ys :: zs
|
|
|
|
where go : a -> List a -> (List1 a, List (List1 a))
|
|
go v [] = (singleton v,[])
|
|
go v (x :: xs) = let (ys,zs) = go x xs
|
|
in if eq v x
|
|
then (cons v ys, zs)
|
|
else (singleton v, ys :: zs)
|
|
|
|
||| The `group` function takes a list of values and returns a list of
|
|
||| lists such that flattening the resulting list is equal to the
|
|
||| argument. Moreover, each list in the resulting list
|
|
||| contains only equal elements.
|
|
public export
|
|
group : Eq a => List a -> List (List1 a)
|
|
group = groupBy (==)
|
|
|
|
||| `groupWith` operates like `group`, but uses the provided projection when
|
|
||| comparing for equality
|
|
public export
|
|
groupWith : Eq b => (a -> b) -> List a -> List (List1 a)
|
|
groupWith f = groupBy (\x,y => f x == f y)
|
|
|
|
||| `groupAllWith` operates like `groupWith`, but sorts the list
|
|
||| first so that each equivalence class has, at most, one list in the
|
|
||| output
|
|
public export
|
|
groupAllWith : Ord b => (a -> b) -> List a -> List (List1 a)
|
|
groupAllWith f = groupWith f . sortBy (comparing f)
|
|
|
|
||| Partitions a list into fixed sized sublists.
|
|
|||
|
|
||| Note: The last list in the result might be shorter than the rest if
|
|
||| the input cannot evenly be split into groups of the same size.
|
|
|||
|
|
||| ```idris example
|
|
||| grouped 3 [1..10] === [[1,2,3],[4,5,6],[7,8,9],[10]]
|
|
||| ```
|
|
public export
|
|
grouped : (n : Nat) -> {auto 0 p : IsSucc n} -> List a -> List (List a)
|
|
grouped _ [] = []
|
|
grouped (S m) (x::xs) = go [<] [<x] m xs
|
|
where
|
|
go : SnocList (List a) -> SnocList a -> Nat -> List a -> List (List a)
|
|
go sxs sx c [] = sxs <>> [sx <>> []]
|
|
go sxs sx 0 (x :: xs) = go (sxs :< (sx <>> [])) [<x] m xs
|
|
go sxs sx (S k) (x :: xs) = go sxs (sx :< x) k xs
|
|
|
|
--------------------------------------------------------------------------------
|
|
-- Properties
|
|
--------------------------------------------------------------------------------
|
|
|
|
-- Nil is not Cons
|
|
export
|
|
Uninhabited ([] = x :: xs) where
|
|
uninhabited Refl impossible
|
|
|
|
-- Cons is not Nil
|
|
export
|
|
Uninhabited (x :: xs = []) where
|
|
uninhabited Refl impossible
|
|
|
|
-- If the heads or the tails of two lists are provably non-equal, then the
|
|
-- combination of the respective heads with their respective tails must be
|
|
-- provably non-equal.
|
|
export
|
|
{0 xs : List a} -> Either (Uninhabited $ x === y) (Uninhabited $ xs === ys) => Uninhabited (x::xs = y::ys) where
|
|
uninhabited @{Left z} Refl = uninhabited @{z} Refl
|
|
uninhabited @{Right z} Refl = uninhabited @{z} Refl
|
|
|
|
||| (::) is injective
|
|
export
|
|
Biinjective Prelude.(::) where
|
|
biinjective Refl = (Refl, Refl)
|
|
|
|
||| Heterogeneous injectivity for (::)
|
|
export
|
|
consInjective : forall x, xs, y, ys .
|
|
the (List a) (x :: xs) = the (List b) (y :: ys) -> (x = y, xs = ys)
|
|
consInjective Refl = (Refl, Refl)
|
|
|
|
lengthPlusIsLengthPlus : (n : Nat) -> (xs : List a) ->
|
|
lengthPlus n xs = n + length xs
|
|
lengthPlusIsLengthPlus n [] = sym $ plusZeroRightNeutral n
|
|
lengthPlusIsLengthPlus n (x::xs) =
|
|
trans
|
|
(lengthPlusIsLengthPlus (S n) xs)
|
|
(plusSuccRightSucc n (length xs))
|
|
|
|
lengthTRIsLength : (xs : List a) -> lengthTR xs = length xs
|
|
lengthTRIsLength = lengthPlusIsLengthPlus Z
|
|
|
|
||| List `reverse` applied to `reverseOnto` is equivalent to swapping the
|
|
||| arguments of `reverseOnto`.
|
|
reverseReverseOnto : (l, r : List a) ->
|
|
reverse (reverseOnto l r) = reverseOnto r l
|
|
reverseReverseOnto _ [] = Refl
|
|
reverseReverseOnto l (x :: xs) = reverseReverseOnto (x :: l) xs
|
|
|
|
||| List `reverse` applied twice yields the identity function.
|
|
export
|
|
reverseInvolutive : (xs : List a) -> reverse (reverse xs) = xs
|
|
reverseInvolutive = reverseReverseOnto []
|
|
|
|
||| Appending `x` to `l` and then reversing the result onto `r` is the same as
|
|
||| using (::) with `x` and the result of reversing `l` onto `r`.
|
|
consReverse : (x : a) -> (l, r : List a) ->
|
|
x :: reverseOnto r l = reverseOnto r (reverseOnto [x] (reverse l))
|
|
consReverse _ [] _ = Refl
|
|
consReverse x (y::ys) r
|
|
= rewrite consReverse x ys (y :: r) in
|
|
rewrite cong (reverseOnto r . reverse) $ consReverse x ys [y] in
|
|
rewrite reverseInvolutive (y :: reverseOnto [x] (reverse ys)) in
|
|
Refl
|
|
|
|
||| Proof that it is safe to lift a (::) out of the first `tailRecAppend`
|
|
||| argument.
|
|
consTailRecAppend : (x : a) -> (l, r : List a) ->
|
|
tailRecAppend (x :: l) r = x :: (tailRecAppend l r)
|
|
consTailRecAppend x l r
|
|
= rewrite consReverse x (reverse l) r in
|
|
rewrite reverseInvolutive l in
|
|
Refl
|
|
|
|
||| Proof that `(++)` and `tailRecAppend` do the same thing, so the %transform
|
|
||| directive is safe.
|
|
tailRecAppendIsAppend : (xs, ys : List a) -> tailRecAppend xs ys = xs ++ ys
|
|
tailRecAppendIsAppend [] ys = Refl
|
|
tailRecAppendIsAppend (x::xs) ys =
|
|
trans (consTailRecAppend x xs ys) (cong (x ::) $ tailRecAppendIsAppend xs ys)
|
|
|
|
||| The empty list is a right identity for append.
|
|
export
|
|
appendNilRightNeutral : (l : List a) -> l ++ [] = l
|
|
appendNilRightNeutral [] = Refl
|
|
appendNilRightNeutral (_::xs) = rewrite appendNilRightNeutral xs in Refl
|
|
|
|
||| Appending lists is associative.
|
|
export
|
|
appendAssociative : (l, c, r : List a) -> l ++ (c ++ r) = (l ++ c) ++ r
|
|
appendAssociative [] c r = Refl
|
|
appendAssociative (_::xs) c r = rewrite appendAssociative xs c r in Refl
|
|
|
|
||| `reverseOnto` reverses the list and prepends it to the "onto" argument
|
|
revOnto : (xs, vs : List a) -> reverseOnto xs vs = reverse vs ++ xs
|
|
revOnto _ [] = Refl
|
|
revOnto xs (v :: vs)
|
|
= rewrite revOnto (v :: xs) vs in
|
|
rewrite appendAssociative (reverse vs) [v] xs in
|
|
rewrite revOnto [v] vs in Refl
|
|
|
|
||| `reverse` is distributive
|
|
export
|
|
revAppend : (vs, ns : List a) -> reverse ns ++ reverse vs = reverse (vs ++ ns)
|
|
revAppend [] ns = rewrite appendNilRightNeutral (reverse ns) in Refl
|
|
revAppend (v :: vs) ns
|
|
= rewrite revOnto [v] vs in
|
|
rewrite revOnto [v] (vs ++ ns) in
|
|
rewrite sym (revAppend vs ns) in
|
|
rewrite appendAssociative (reverse ns) (reverse vs) [v] in
|
|
Refl
|
|
|
|
||| Dropping `m` elements from `l` and then dropping `n` elements from the
|
|
||| result, is the same as simply dropping `n+m` elements from `l`
|
|
export
|
|
dropFusion : (n, m : Nat) -> (l : List t) -> drop n (drop m l) = drop (n+m) l
|
|
dropFusion Z m l = Refl
|
|
dropFusion (S n) Z l = rewrite plusZeroRightNeutral n in Refl
|
|
dropFusion (S n) (S m) [] = Refl
|
|
dropFusion (S n) (S m) (x::l) = rewrite plusAssociative n 1 m in
|
|
rewrite plusCommutative n 1 in
|
|
dropFusion (S n) m l
|
|
|
|
||| Mapping a function over a list does not change the length of the list.
|
|
export
|
|
lengthMap : (xs : List a) -> length (map f xs) = length xs
|
|
lengthMap [] = Refl
|
|
lengthMap (x :: xs) = cong S (lengthMap xs)
|
|
|
|
||| Proof that replicate produces a list of the requested length.
|
|
export
|
|
lengthReplicate : (n : Nat) -> length (replicate n x) = n
|
|
lengthReplicate 0 = Refl
|
|
lengthReplicate (S k) = cong S (lengthReplicate k)
|
|
|
|
export
|
|
foldlAppend : (f : acc -> a -> acc) -> (init : acc) -> (xs : List a) -> (ys : List a) -> foldl f init (xs ++ ys) = foldl f (foldl f init xs) ys
|
|
foldlAppend f init [] ys = Refl
|
|
foldlAppend f init (x::xs) ys = rewrite foldlAppend f (f init x) xs ys in Refl
|
|
|
|
export
|
|
filterAppend : (f : a -> Bool) -> (xs, ys : List a) -> filter f (xs ++ ys) = filter f xs ++ filter f ys
|
|
filterAppend f [] ys = Refl
|
|
filterAppend f (x::xs) ys with (f x)
|
|
_ | False = rewrite filterAppend f xs ys in Refl
|
|
_ | True = rewrite filterAppend f xs ys in Refl
|
|
|
|
export
|
|
mapMaybeFusion : (g : b -> Maybe c) -> (f : a -> Maybe b) -> (xs : List a) -> mapMaybe g (mapMaybe f xs) = mapMaybe (f >=> g) xs
|
|
mapMaybeFusion g f [] = Refl
|
|
mapMaybeFusion g f (x::xs) with (f x)
|
|
_ | Nothing = mapMaybeFusion g f xs
|
|
_ | (Just y) with (g y)
|
|
_ | Nothing = mapMaybeFusion g f xs
|
|
_ | (Just z) = rewrite mapMaybeFusion g f xs in Refl
|
|
|
|
export
|
|
mapMaybeAppend : (f : a -> Maybe b) -> (xs, ys : List a) -> mapMaybe f (xs ++ ys) = mapMaybe f xs ++ mapMaybe f ys
|
|
mapMaybeAppend f [] ys = Refl
|
|
mapMaybeAppend f (x::xs) ys with (f x)
|
|
_ | Nothing = rewrite mapMaybeAppend f xs ys in Refl
|
|
_ | (Just y) = rewrite mapMaybeAppend f xs ys in Refl
|
|
|
|
export
|
|
mapFusion : (g : b -> c) -> (f : a -> b) -> (xs : List a) -> map g (map f xs) = map (g . f) xs
|
|
mapFusion g f [] = Refl
|
|
mapFusion g f (x::xs) = rewrite mapFusion g f xs in Refl
|
|
|
|
export
|
|
mapAppend : (f : a -> b) -> (xs, ys : List a) -> map f (xs ++ ys) = map f xs ++ map f ys
|
|
mapAppend f [] ys = Refl
|
|
mapAppend f (x::xs) ys = rewrite mapAppend f xs ys in Refl
|
|
|
|
0 mapTRIsMap : (f : a -> b) -> (as : List a) -> mapTR f as === map f as
|
|
mapTRIsMap f = lemma Lin
|
|
where lemma : (sb : SnocList b)
|
|
-> (as : List a)
|
|
-> mapAppend sb f as === (sb <>> map f as)
|
|
lemma sb [] = Refl
|
|
lemma sb (x :: xs) = lemma (sb :< f x) xs
|
|
|
|
|
|
0 mapMaybeTRIsMapMaybe : (f : a -> Maybe b)
|
|
-> (as : List a)
|
|
-> mapMaybeTR f as === mapMaybe f as
|
|
mapMaybeTRIsMapMaybe f = lemma Lin
|
|
where lemma : (sb : SnocList b)
|
|
-> (as : List a)
|
|
-> mapMaybeAppend sb f as === (sb <>> mapMaybe f as)
|
|
lemma sb [] = Refl
|
|
lemma sb (x :: xs) with (f x)
|
|
lemma sb (x :: xs) | Nothing = lemma sb xs
|
|
lemma sb (x :: xs) | Just v = lemma (sb :< v) xs
|
|
|
|
0 filterTRIsFilter : (f : a -> Bool)
|
|
-> (as : List a)
|
|
-> filterTR f as === filter f as
|
|
filterTRIsFilter f = lemma Lin
|
|
|
|
where lemma : (sa : SnocList a)
|
|
-> (as : List a)
|
|
-> filterAppend sa f as === (sa <>> filter f as)
|
|
lemma sa [] = Refl
|
|
lemma sa (x :: xs) with (f x)
|
|
lemma sa (x :: xs) | False = lemma sa xs
|
|
lemma sa (x :: xs) | True = lemma (sa :< x) xs
|
|
|
|
0 replicateTRIsReplicate : (n : Nat) -> (x : a) -> replicateTR [] n x === replicate n x
|
|
replicateTRIsReplicate n x = trans (lemma [] n) (appendNilRightNeutral _)
|
|
where lemma1 : (as : List a) -> (m : Nat) -> (x :: replicate m x) ++ as === replicate m x ++ (x :: as)
|
|
lemma1 as 0 = Refl
|
|
lemma1 as (S k) = cong (x ::) (lemma1 as k)
|
|
|
|
lemma : (as : List a) -> (m : Nat) -> replicateTR as m x === replicate m x ++ as
|
|
lemma as 0 = Refl
|
|
lemma as (S k) =
|
|
let prf := lemma (x :: as) k
|
|
in trans prf (sym $ lemma1 as k)
|