Agda-2.6.4.2: A dependently typed functional programming language and proof assistant
Safe HaskellNone
LanguageHaskell2010

Agda.Utils.List

Description

Utility functions for lists.

Synopsis

Variants of list case, cons, head, tail, init, last

snoc :: [a] -> a -> [a] Source #

Append a single element at the end. Time: O(length); use only on small lists.

caseList :: [a] -> b -> (a -> [a] -> b) -> b Source #

Case distinction for lists, with list first. O(1).

Cf. ifNull.

caseListM :: Monad m => m [a] -> m b -> (a -> [a] -> m b) -> m b Source #

Case distinction for lists, with list first. O(1).

Cf. ifNull.

listCase :: b -> (a -> [a] -> b) -> [a] -> b Source #

Case distinction for lists, with list last. O(1).

headWithDefault :: a -> [a] -> a Source #

Head function (safe). Returns a default value on empty lists. O(1).

headWithDefault 42 []      = 42
headWithDefault 42 [1,2,3] = 1

tailMaybe :: [a] -> Maybe [a] Source #

Tail function (safe). O(1).

tailWithDefault :: [a] -> [a] -> [a] Source #

Tail function (safe). Returns a default list on empty lists. O(1).

lastMaybe :: [a] -> Maybe a Source #

Last element (safe). O(n).

lastWithDefault :: a -> [a] -> a Source #

Last element (safe). Returns a default list on empty lists. O(n).

last1 :: a -> [a] -> a Source #

Last element of non-empty list (safe). O(n). last1 a as = last (a : as)

last2 :: [a] -> Maybe (a, a) Source #

Last two elements (safe). O(n).

last2' :: a -> a -> [a] -> (a, a) Source #

last2' x y zs computes the last two elements of x:y:zs. O(n).

uncons :: [a] -> Maybe (a, [a]) Source #

Opposite of cons (:), safe. O(1).

mcons :: Maybe a -> [a] -> [a] Source #

Maybe cons. O(1). mcons ma as = maybeToList ma ++ as

initLast :: [a] -> Maybe ([a], a) Source #

init and last in one go, safe. O(n).

initLast1 :: a -> [a] -> ([a], a) Source #

init and last of non-empty list, safe. O(n). initLast1 a as = (init (a:as), last (a:as)

init1 :: a -> [a] -> [a] Source #

init of non-empty list, safe. O(n). init1 a as = init (a:as)

initMaybe :: [a] -> Maybe [a] Source #

init, safe. O(n).

initWithDefault :: [a] -> [a] -> [a] Source #

init, safe. O(n).

Lookup and indexing

(!!!) :: [a] -> Int -> Maybe a Source #

Lookup function (safe). O(min n index).

(!!) :: HasCallStack => [a] -> Int -> a Source #

A variant of !! that might provide more informative error messages if the index is out of bounds.

Precondition: The index should not be out of bounds.

indexWithDefault :: a -> [a] -> Int -> a Source #

Lookup function with default value for index out of range. O(min n index).

The name is chosen akin to genericIndex.

findWithIndex :: (a -> Bool) -> [a] -> Maybe (a, Int) Source #

Find an element satisfying a predicate and return it with its index. O(n) in the worst case, e.g. findWithIndex f xs = Nothing.

TODO: more efficient implementation!?

genericElemIndex :: (Eq a, Integral i) => a -> [a] -> Maybe i Source #

A generalised variant of elemIndex. O(n).

downFrom :: Integral a => a -> [a] Source #

downFrom n = [n-1,..1,0]. O(n).

Update

updateHead :: (a -> a) -> [a] -> [a] Source #

Update the first element of a list, if it exists. O(1).

updateLast :: (a -> a) -> [a] -> [a] Source #

Update the last element of a list, if it exists. O(n).

updateAt :: Int -> (a -> a) -> [a] -> [a] Source #

Update nth element of a list, if it exists. O(min index n).

Precondition: the index is >= 0.

Sublist extraction and partitioning

type Prefix a Source #

Arguments

 = [a]

The list before the split point.

type Suffix a Source #

Arguments

 = [a]

The list after the split point.

splitExactlyAt :: Integral n => n -> [a] -> Maybe (Prefix a, Suffix a) Source #

splitExactlyAt n xs = Just (ys, zs) iff xs = ys ++ zs and genericLength ys = n.

dropEnd :: Int -> [a] -> Prefix a Source #

Drop from the end of a list. O(length).

dropEnd n = reverse . drop n . reverse

Forces the whole list even for n==0.

spanEnd :: (a -> Bool) -> [a] -> (Prefix a, Suffix a) Source #

Split off the largest suffix whose elements satisfy a predicate. O(n).

spanEnd p xs = (ys, zs) where xs = ys ++ zs and all p zs and maybe True (not . p) (lastMaybe yz).

breakAfter1 :: (a -> Bool) -> a -> [a] -> (List1 a, [a]) Source #

Breaks a list just after an element satisfying the predicate is found.

>>> breakAfter1 even 1 [3,5,2,4,7,8]
(1 :| [3,5,2],[4,7,8])

breakAfter :: (a -> Bool) -> [a] -> ([a], [a]) Source #

Breaks a list just after an element satisfying the predicate is found.

>>> breakAfter even [1,3,5,2,4,7,8]
([1,3,5,2],[4,7,8])

takeWhileJust :: (a -> Maybe b) -> [a] -> Prefix b Source #

A generalized version of takeWhile. (Cf. mapMaybe vs. filter). @O(length . takeWhileJust f).

takeWhileJust f = fst . spanJust f.

spanJust :: (a -> Maybe b) -> [a] -> (Prefix b, Suffix a) Source #

A generalized version of span. O(length . fst . spanJust f).

partitionMaybe :: (a -> Maybe b) -> [a] -> ([a], [b]) Source #

Partition a list into Nothings and Justs. O(n).

partitionMaybe f = partitionEithers . map ( a -> maybe (Left a) Right (f a))

Note: mapMaybe f = snd . partitionMaybe f.

filterAndRest :: (a -> Bool) -> [a] -> ([a], Suffix a) Source #

Like filter, but additionally return the last partition of the list where the predicate is False everywhere. O(n).

mapMaybeAndRest :: (a -> Maybe b) -> [a] -> ([b], Suffix a) Source #

Like mapMaybe, but additionally return the last partition of the list where the function always returns Nothing. O(n).

isSublistOf :: Eq a => [a] -> [a] -> Bool Source #

Sublist relation.

holes :: [a] -> [(a, [a])] Source #

All ways of removing one element from a list. O(n²).

Prefix and suffix

Prefix

commonPrefix :: Eq a => [a] -> [a] -> Prefix a Source #

Compute the common prefix of two lists. O(min n m).

dropCommon :: [a] -> [b] -> (Suffix a, Suffix b) Source #

Drops from both lists simultaneously until one list is empty. O(min n m).

stripPrefixBy :: (a -> a -> Bool) -> Prefix a -> [a] -> Maybe (Suffix a) Source #

Check if a list has a given prefix. If so, return the list minus the prefix. O(length prefix).

Suffix

commonSuffix :: Eq a => [a] -> [a] -> Suffix a Source #

Compute the common suffix of two lists. O(n + m).

stripSuffix :: Eq a => Suffix a -> [a] -> Maybe (Prefix a) Source #

stripSuffix suf xs = Just pre iff xs = pre ++ suf. O(n).

type ReversedSuffix a = [a] Source #

stripReversedSuffix :: Eq a => ReversedSuffix a -> [a] -> Maybe (Prefix a) Source #

stripReversedSuffix rsuf xs = Just pre iff xs = pre ++ reverse suf. O(n).

data StrSufSt a Source #

Internal state for stripping suffix.

Constructors

SSSMismatch

Error.

SSSStrip (ReversedSuffix a)

"Negative string" to remove from end. List may be empty.

SSSResult [a]

"Positive string" (result). Non-empty list.

suffixesSatisfying :: (a -> Bool) -> [a] -> [Bool] Source #

Returns a list with one boolean for each non-empty suffix of the list, starting with the longest suffix (the entire list). Each boolean is True exactly when every element in the corresponding suffix satisfies the predicate.

An example: suffixesSatisfying isLower AbCde = [False, False, False, True, True]

For total predicates p and finite and total lists xs the following holds: suffixesSatisfying p xs = map (all p) (init (tails xs))

Finding overlap

findOverlap :: Eq a => [a] -> [a] -> (Int, Int) Source #

Find the longest suffix of the first string xs that is a prefix of the second string ys. So, basically, find the overlap where the strings can be glued together. Returns the index where the overlap starts and the length of the overlap. The length of the overlap plus the index is the length of the first string. Note that in the worst case, the empty overlap (length xs,0) is returned.

Worst-case time complexity is quadratic: O(min(n,m)²) where n = length xs and m = length ys.

There might be asymptotically better implementations following Knuth-Morris-Pratt (KMP), but for rather short lists this is good enough.

Chunks

chop :: Int -> [a] -> [[a]] Source #

Chop up a list in chunks of a given length. O(n).

chopWhen :: (a -> Bool) -> [a] -> [[a]] Source #

Chop a list at the positions when the predicate holds. Contrary to wordsBy, consecutive separator elements will result in an empty segment in the result. O(n).

intercalate [x] (chopWhen (== x) xs) == xs

List as sets

hasElem :: Ord a => [a] -> a -> Bool Source #

Check membership for the same list often. Use partially applied to create membership predicate hasElem xs :: a -> Bool.

  • First time: O(n log n) in the worst case.
  • Subsequently: O(log n).

Specification: hasElem xs == (elem xs).

sorted :: Ord a => [a] -> Bool Source #

Check whether a list is sorted. O(n).

Assumes that the Ord instance implements a partial order.

allConsecutive :: (a -> a -> Bool) -> [a] -> Bool Source #

Check whether all consecutive elements of a list satisfy the given relation. O(n).

distinct :: Eq a => [a] -> Bool Source #

Check whether all elements in a list are distinct from each other. Assumes that the Eq instance stands for an equivalence relation.

O(n²) in the worst case distinct xs == True.

fastDistinct :: Ord a => [a] -> Bool Source #

An optimised version of distinct. O(n log n).

Precondition: The list's length must fit in an Int.

duplicates :: Ord a => [a] -> [a] Source #

Returns an (arbitrary) representative for each list element that occurs more than once. O(n log n).

allDuplicates :: Ord a => [a] -> [a] Source #

Remove the first representative for each list element. Thus, returns all duplicate copies. O(n log n).

allDuplicates xs == sort $ xs \ nub xs.

nubAndDuplicatesOn :: Ord b => (a -> b) -> [a] -> ([a], [a]) Source #

Partition a list into first and later occurrences of elements (modulo some quotient given by a representation function).

Time: O(n log n).

Specification:

nubAndDuplicatesOn f xs = (ys, xs List.\\ ys)
  where ys = nubOn f xs

nubOn :: Ord b => (a -> b) -> [a] -> [a] Source #

Efficient variant of nubBy for lists, using a set to store already seen elements. O(n log n)

Specification:

nubOn f xs == 'nubBy' ((==) `'on'` f) xs.

nubFavouriteOn Source #

Arguments

:: forall a b c. (Ord b, Eq c, Hashable c) 
=> (a -> b)

The values returned by this function are used to determine which element from a group of equal elements that is returned: the smallest one is chosen (and if two elements are equally small, then the first one is chosen).

-> (a -> c)

Two elements are treated as equal if this function returns the same value for both elements.

-> [a] 
-> [a] 

A variant of nubOn that is parametrised by a function that is used to select which element from a group of equal elements that is returned. The returned elements keep the order that they had in the input list.

Precondition: The length of the input list must be at most maxBound :: Int.

uniqOn :: Ord b => (a -> b) -> [a] -> [a] Source #

Efficient variant of nubBy for finite lists. O(n log n).

uniqOn f == 'List.sortBy' (compare `'on'` f) . 'nubBy' ((==) `'on'` f)

If there are several elements with the same f-representative, the first of these is kept.

allEqual :: Eq a => [a] -> Bool Source #

Checks if all the elements in the list are equal. Assumes that the Eq instance stands for an equivalence relation. O(n).

nubM :: Monad m => (a -> a -> m Bool) -> [a] -> m [a] Source #

Non-efficient, monadic nub. O(n²).

Zipping

zipWith' :: (a -> b -> c) -> [a] -> [b] -> Maybe [c] Source #

Requires both lists to have the same length. O(n).

Otherwise, Nothing is returned.

zipWithKeepRest :: (a -> b -> b) -> [a] -> [b] -> [b] Source #

Like zipWith but keep the rest of the second list as-is (in case the second list is longer). O(n).

  zipWithKeepRest f as bs == zipWith f as bs ++ drop (length as) bs

Unzipping

unzipWith :: (a -> (b, c)) -> [a] -> ([b], [c]) Source #

Edit distance

editDistanceSpec :: Eq a => [a] -> [a] -> Int Source #

Implemented using tree recursion, don't run me at home! O(3^(min n m)).

editDistance :: Eq a => [a] -> [a] -> Int Source #

Implemented using dynamic programming and Data.Array. O(n*m).

mergeStrictlyOrderedBy :: (a -> a -> Bool) -> [a] -> [a] -> Maybe [a] Source #