216 lines
4.4 KiB
Haskell
216 lines
4.4 KiB
Haskell
-- Author: Danila Fedorin, Thursday, January 10
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module HW1 where
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-- | Integer-labeled binary trees.
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data Tree
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= Node Int Tree Tree -- ^ Internal nodes
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| Leaf Int -- ^ Leaf nodes
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deriving (Eq,Show)
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-- | An example binary tree, which will be used in tests.
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t1 :: Tree
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t1 = Node 1 (Node 2 (Node 3 (Leaf 4) (Lea 5))
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(Leaf 6))
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(Node 7 (Leaf 8) (Leaf 9))
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-- | Another example binary tree, used in tests.
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t2 :: Tree
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t2 = Node 6 (Node 2 (Leaf 1) (Node 4 (Leaf 3) (Leaf 5)))
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(Node 8 (Leaf 7) (Leaf 9))
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-- | Right associative fold.
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-- The best way here would be to add a foldable instance for Tree.
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-- however, since Tree doesn't take a type parameter, this is not possible.
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-- We settle for these functions.
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treeFoldr :: (Int -> a -> a) -> a -> Tree -> a
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treeFoldr f a (Leaf i) = f i a
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treeFoldr f a (Node i l r) = treeFoldr f (f i (treeFoldr f a r)) l
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-- | foldr for non-empty lists.
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treeFoldr1 :: (Int -> Int -> Int) -> Tree -> Int
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treeFoldr1 _ (Leaf i) = i
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treeFoldr1 f (Node i l r) = treeFoldr f (f i (treeFoldr1 f r)) l
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-- | Left associative fold.
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treeFoldl :: (Int -> a -> a) -> a -> Tree -> a
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treeFoldl f a (Leaf i) = f i a
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treeFoldl f a (Node i l r) = treeFoldl f (f i (treeFoldl f a l)) r
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-- | foldl for non-empty lists.
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treeFoldl1 :: (Int -> Int -> Int) -> Tree -> Int
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treeFoldl1 _ (Leaf i) = i
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treeFoldl1 f (Node i l r) = treeFoldl f (f i (treeFoldl1 f l)) r
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-- | In-order traversal fold.
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treeFold :: (Int -> a -> a) -> a -> Tree -> a
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treeFold f a (Leaf i) = f i a
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treeFold f a (Node i l r) = f i $ treeFold f (treeFold f a r) l
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-- | The integer at the left-most node of a binary tree.
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--
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-- >>> leftmost (Leaf 3)
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-- 3
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--
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-- >>> leftmost (Node 5 (Leaf 6) (Leaf 7))
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-- 6
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--
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-- >>> leftmost t1
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-- 4
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--
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-- >>> leftmost t2
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-- 1
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--
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leftmost :: Tree -> Int
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leftmost = treeFoldr1 (\a _ -> a)
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-- | The integer at the right-most node of a binary tree.
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--
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-- >>> rightmost (Leaf 3)
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-- 3
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--
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-- >>> rightmost (Node 5 (Leaf 6) (Leaf 7))
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-- 7
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--
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-- >>> rightmost t1
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-- 9
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--
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-- >>> rightmost t2
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-- 9
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--
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rightmost :: Tree -> Int
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rightmost = treeFoldl1 (\a _ -> a)
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-- | Get the maximum integer from a binary tree.
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--
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-- >>> maxInt (Leaf 3)
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-- 3
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--
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-- >>> maxInt (Node 5 (Leaf 4) (Leaf 2))
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-- 5
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--
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-- >>> maxInt (Node 5 (Leaf 7) (Leaf 2))
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-- 7
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--
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-- >>> maxInt t1
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-- 9
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--
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-- >>> maxInt t2
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-- 9
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--
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maxInt :: Tree -> Int
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maxInt = treeFoldr1 max
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-- | Get the minimum integer from a binary tree.
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--
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-- >>> minInt (Leaf 3)
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-- 3
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--
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-- >>> minInt (Node 2 (Leaf 5) (Leaf 4))
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-- 2
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--
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-- >>> minInt (Node 5 (Leaf 4) (Leaf 7))
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-- 4
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--
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-- >>> minInt t1
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-- 1
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--
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-- >>> minInt t2
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-- 1
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--
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minInt :: Tree -> Int
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minInt = treeFoldr1 min
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-- | Get the sum of the integers in a binary tree.
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--
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-- >>> sumInts (Leaf 3)
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-- 3
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--
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-- >>> sumInts (Node 2 (Leaf 5) (Leaf 4))
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-- 11
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--
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-- >>> sumInts t1
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-- 45
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--
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-- >>> sumInts (Node 10 t1 t2)
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-- 100
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--
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sumInts :: Tree -> Int
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sumInts = treeFoldr1 (+)
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-- | The list of integers encountered by a pre-order traversal of the tree.
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--
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-- >>> preorder (Leaf 3)
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-- [3]
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--
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-- >>> preorder (Node 5 (Leaf 6) (Leaf 7))
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-- [5,6,7]
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--
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-- >>> preorder t1
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-- [1,2,3,4,5,6,7,8,9]
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--
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-- >>> preorder t2
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-- [6,2,1,4,3,5,8,7,9]
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--
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preorder :: Tree -> [ Int ]
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preorder = treeFold (:) []
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-- | The list of integers encountered by an in-order traversal of the tree.
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--
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-- >>> inorder (Leaf 3)
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-- [3]
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--
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-- >>> inorder (Node 5 (Leaf 6) (Leaf 7))
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-- [6,5,7]
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--
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-- >>> inorder t1
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-- [4,3,5,2,6,1,8,7,9]
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--
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-- >>> inorder t2
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-- [1,2,3,4,5,6,7,8,9]
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--
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inorder :: Tree -> [ Int ]
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inorder = treeFoldr (:) []
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-- | Check whether a binary tree is a binary search tree.
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--
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-- >>> isBST (Leaf 3)
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-- True
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--
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-- >>> isBST (Node 5 (Leaf 6) (Leaf 7))
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-- False
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--
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-- >>> isBST t1
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-- False
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--
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-- >>> isBST t2
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-- True
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--
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isBST :: Tree -> Bool
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isBST tree = snd $ treeFoldl accCompare (firstNum, True) tree
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where
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accCompare v (p, b) = (v, b && v >= p)
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firstNum = leftmost tree
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-- | Check whether a number is contained in a binary search tree.
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-- (You may assume that the given tree is a binary search tree.)
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--
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-- >>> inBST 2 (Node 5 (Leaf 2) (Leaf 7))
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-- True
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--
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-- >>> inBST 3 (Node 5 (Leaf 2) (Leaf 7))
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-- False
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--
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-- >>> inBST 4 t2
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-- True
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--
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-- >>> inBST 10 t2
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-- False
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--
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inBST :: Int -> Tree -> Bool
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inBST i = treeFoldr (\v acc -> acc || (v == i)) False
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