Skew heap
A skew heap (or self-adjusting heap) is a heap data structure implemented as a binary tree. Skew heaps are advantageous because of their ability to merge more quickly than binary heaps. In contrast with binary heaps, there are no structural constraints, so there is no guarantee that the height of the tree is logarithmic. Only two conditions must be satisfied:
- The general heap order must be enforced
- Every operation (add, remove_min, merge) on two skew heaps must be done using a special skew heap merge.
A skew heap is a self-adjusting form of a leftist heap which attempts to maintain balance by unconditionally swapping all nodes in the merge path when merging two heaps. (The merge operation is also used when adding and removing values.) With no structural constraints, it may seem that a skew heap would be horribly inefficient. However, amortized complexity analysis can be used to demonstrate that all operations on a skew heap can be done in O(log n).[1] In fact, with denoting the golden ratio, the exact amortized complexity is known to be logφ n (approximately 1.44 log2 n).[2][3]
Definition[]
Skew heaps may be described with the following recursive definition:[citation needed]
- A heap with only one element is a skew heap.
- The result of skew merging two skew heaps and is also a skew heap.
Operations[]
Merging two heaps[]
When two skew heaps are to be merged, we can use a similar process as the merge of two leftist heaps:
- Compare roots of two heaps; let p be the heap with the smaller root, and q be the other heap. Let r be the name of the resulting new heap.
- Let the root of r be the root of p (the smaller root), and let r's right subtree be p's left subtree.
- Now, compute r's left subtree by recursively merging p's right subtree with q.
template<class T, class CompareFunction>
SkewNode<T>* CSkewHeap<T, CompareFunction>::_Merge(SkewNode<T>* root_1, SkewNode<T>* root_2)
{
SkewNode<T>* firstRoot = root_1;
SkewNode<T>* secondRoot = root_2;
if (firstRoot == NULL)
return secondRoot;
else if (secondRoot == NULL)
return firstRoot;
if (sh_compare->Less(firstRoot->key, secondRoot->key))
{
SkewNode<T>* tempHeap = firstRoot->rightNode;
firstRoot->rightNode = firstRoot->leftNode;
firstRoot->leftNode = _Merge(secondRoot, tempHeap);
return firstRoot;
}
else
return _Merge(secondRoot, firstRoot);
}
Before:
after
Non-recursive merging[]
Alternatively, there is a non-recursive approach which is more wordy, and does require some sorting at the outset.
- Split each heap into subtrees by cutting every path. (From the root node, sever the right node and make the right child its own subtree.) This will result in a set of trees in which the root either only has a left child or no children at all.
- Sort the subtrees in ascending order based on the value of the root node of each subtree.
- While there are still multiple subtrees, iteratively recombine the last two (from right to left).
- If the root of the second-to-last subtree has a left child, swap it to be the right child.
- Link the root of the last subtree as the left child of the second-to-last subtree.
Adding values[]
Adding a value to a skew heap is like merging a tree with one node together with the original tree.
Removing values[]
Removing the first value in a heap can be accomplished by removing the root and merging its child subtrees.
Implementation[]
In many functional languages, skew heaps become extremely simple to implement. Here is a complete sample implementation in Haskell.
data SkewHeap a = Empty
| Node a (SkewHeap a) (SkewHeap a)
singleton :: Ord a => a -> SkewHeap a
singleton x = Node x Empty Empty
union :: Ord a => SkewHeap a -> SkewHeap a -> SkewHeap a
Empty `union` t2 = t2
t1 `union` Empty = t1
t1@(Node x1 l1 r1) `union` t2@(Node x2 l2 r2)
| x1 <= x2 = Node x1 (t2 `union` r1) l1
| otherwise = Node x2 (t1 `union` r2) l2
insert :: Ord a => a -> SkewHeap a -> SkewHeap a
insert x heap = singleton x `union` heap
extractMin :: Ord a => SkewHeap a -> Maybe (a, SkewHeap a)
extractMin Empty = Nothing
extractMin (Node x l r) = Just (x, l `union` r)
References[]
- ^ Sleator, Daniel Dominic; Tarjan, Robert Endre (February 1986). "Self-Adjusting Heaps". SIAM Journal on Computing. 15 (1): 52–69. CiteSeerX 10.1.1.93.6678. doi:10.1137/0215004. ISSN 0097-5397.
- ^ Kaldewaij, Anne; Schoenmakers, Berry (1991). "The Derivation of a Tighter Bound for Top-Down Skew Heaps" (PDF). Information Processing Letters. 37 (5): 265–271. CiteSeerX 10.1.1.56.8717. doi:10.1016/0020-0190(91)90218-7.
- ^ Schoenmakers, Berry (1997). "A Tight Lower Bound for Top-Down Skew Heaps" (PDF). Information Processing Letters. 61 (5): 279–284. CiteSeerX 10.1.1.47.447. doi:10.1016/S0020-0190(97)00028-8.
External links[]
- Binary trees
- Heaps (data structures)