Safe Haskell | None |
---|---|

Language | Haskell2010 |

## Synopsis

- data BinLeafTree v a
- = Leaf !a
- | Node (BinLeafTree v a) !v (BinLeafTree v a)

- class Semigroup v => Measured v a | a -> v where
- node :: Measured v a => BinLeafTree v a -> BinLeafTree v a -> BinLeafTree v a
- asBalancedBinLeafTree :: NonEmpty a -> BinLeafTree Size (Elem a)
- foldUp :: (b -> v -> b -> b) -> (a -> b) -> BinLeafTree v a -> b
- foldUpData :: (w -> v -> w -> w) -> (a -> w) -> BinLeafTree v a -> BinLeafTree w a
- zipExactWith :: (u -> v -> w) -> (a -> b -> c) -> BinLeafTree u a -> BinLeafTree v b -> BinLeafTree w c
- newtype Size = Size Int
- newtype Elem a = Elem {
- _unElem :: a

- data Sized a = Sized !Size a
- data RoseElem v a
- = InternalNode v
- | LeafNode a

- toRoseTree :: BinLeafTree v a -> Tree (RoseElem v a)
- drawTree :: (Show v, Show a) => BinLeafTree v a -> String
- data BinaryTree a
- = Nil
- | Internal (BinaryTree a) !a (BinaryTree a)

- access :: BinaryTree a -> Maybe a
- asBalancedBinTree :: [a] -> BinaryTree a
- foldBinaryUp :: b -> (a -> b -> b -> b) -> BinaryTree a -> BinaryTree (a, b)
- toRoseTree' :: BinaryTree a -> Maybe (Tree a)
- drawTree' :: Show a => BinaryTree a -> String

# Documentation

data BinLeafTree v a Source #

Leaf !a | |

Node (BinLeafTree v a) !v (BinLeafTree v a) |

## Instances

class Semigroup v => Measured v a | a -> v where Source #

## Instances

Measured Size (Elem a) Source # | |

Measured v a => Measured v (BinLeafTree v a) Source # | |

Defined in Data.BinaryTree measure :: BinLeafTree v a -> v Source # | |

Semigroup v => Measured v (NodeData d r v) Source # | |

Measured [I a] (I a) Source # | |

node :: Measured v a => BinLeafTree v a -> BinLeafTree v a -> BinLeafTree v a Source #

smart constructor

asBalancedBinLeafTree :: NonEmpty a -> BinLeafTree Size (Elem a) Source #

Create a balanced tree, i.e. a tree of height \(O(\log n)\) with the elements in the leaves.

\(O(n)\) time.

foldUp :: (b -> v -> b -> b) -> (a -> b) -> BinLeafTree v a -> b Source #

Given a function to combine internal nodes into b's and leafs into b's, traverse the tree bottom up, and combine everything into one b.

foldUpData :: (w -> v -> w -> w) -> (a -> w) -> BinLeafTree v a -> BinLeafTree w a Source #

Traverses the tree bottom up, recomputing the assocated values.

zipExactWith :: (u -> v -> w) -> (a -> b -> c) -> BinLeafTree u a -> BinLeafTree v b -> BinLeafTree w c Source #

Takes two trees, that have the same structure, and uses the provided functions to "zip" them together

## Instances

Enum Size Source # | |

Eq Size Source # | |

Integral Size Source # | |

Num Size Source # | |

Ord Size Source # | |

Read Size Source # | |

Real Size Source # | |

Defined in Data.BinaryTree toRational :: Size -> Rational # | |

Show Size Source # | |

Generic Size Source # | |

Semigroup Size Source # | |

Monoid Size Source # | |

NFData Size Source # | |

Defined in Data.BinaryTree | |

Measured Size (Elem a) Source # | |

type Rep Size Source # | |

Defined in Data.BinaryTree |

## Instances

Functor Elem Source # | |

Foldable Elem Source # | |

Defined in Data.BinaryTree fold :: Monoid m => Elem m -> m # foldMap :: Monoid m => (a -> m) -> Elem a -> m # foldr :: (a -> b -> b) -> b -> Elem a -> b # foldr' :: (a -> b -> b) -> b -> Elem a -> b # foldl :: (b -> a -> b) -> b -> Elem a -> b # foldl' :: (b -> a -> b) -> b -> Elem a -> b # foldr1 :: (a -> a -> a) -> Elem a -> a # foldl1 :: (a -> a -> a) -> Elem a -> a # elem :: Eq a => a -> Elem a -> Bool # maximum :: Ord a => Elem a -> a # | |

Traversable Elem Source # | |

Measured Size (Elem a) Source # | |

Eq a => Eq (Elem a) Source # | |

Ord a => Ord (Elem a) Source # | |

Read a => Read (Elem a) Source # | |

Show a => Show (Elem a) Source # | |

## Instances

# Converting into a Data.Tree

InternalNode v | |

LeafNode a |

toRoseTree :: BinLeafTree v a -> Tree (RoseElem v a) Source #

# Internal Node Tree

data BinaryTree a Source #

Nil | |

Internal (BinaryTree a) !a (BinaryTree a) |

## Instances

access :: BinaryTree a -> Maybe a Source #

Get the element stored at the root, if it exists

asBalancedBinTree :: [a] -> BinaryTree a Source #

Create a balanced binary tree

\(O(n)\)

foldBinaryUp :: b -> (a -> b -> b -> b) -> BinaryTree a -> BinaryTree (a, b) Source #

toRoseTree' :: BinaryTree a -> Maybe (Tree a) Source #