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AVL Trees ITCS6114 Algorithms and Data Structures.

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1 AVL Trees ITCS6114 Algorithms and Data Structures

2 AVL Trees2 Balanced and unbalanced BST 4 25 13 1 5 2 4 3 7 6 4 26 5713 Is this “balanced”?

3 AVL Trees3 Perfect Balance Want a complete tree after every operation ›tree is full except possibly in the lower right This is expensive ›For example, insert 2 in the tree on the left and then rebuild as a complete tree Insert 2 & complete tree 6 49 815 5 28 6914

4 AVL Trees4 AVL - Good but not Perfect Balance AVL trees are height-balanced binary search trees Balance factor of a node ›height(left subtree) - height(right subtree) An AVL tree has balance factor calculated at every node ›For every node, heights of left and right subtree can differ by no more than 1 ›Store current heights in each node

5 AVL Trees5 Node Heights 1 00 2 0 6 49 815 1 height of node = h balance factor = h left -h right empty height = -1 0 0 height=2 BF=1-0=1 0 6 49 15 1 Tree A (AVL)Tree B (AVL)

6 AVL Trees6 Node Heights after Insert 7 2 10 3 0 6 49 815 1 height of node = h balance factor = h left -h right empty height = -1 1 0 2 0 6 49 15 1 0 7 0 7 balance factor 1-(-1) = 2 Tree A (AVL)Tree B (not AVL)

7 AVL Trees7 Insert and Rotation in AVL Trees Insert operation may cause balance factor to become 2 or –2 for some node ›only nodes on the path from insertion point to root node have possibly changed in height ›So after the Insert, go back up to the root node by node, updating heights ›If a new balance factor (the difference h left - h right ) is 2 or –2, adjust tree by rotation around the node

8 AVL Trees8 Single Rotation in an AVL Tree 2 10 2 0 6 49 815 1 0 7 0 1 0 2 0 6 4 9 8 15 1 0 7

9 AVL Trees9 Let the node that needs rebalancing be . There are 4 cases: Outside Cases (require single rotation) : 1. Insertion into left subtree of left child of . 2. Insertion into right subtree of right child of . Inside Cases (require double rotation) : 3. Insertion into right subtree of left child of . 4. Insertion into left subtree of right child of . The rebalancing is performed through four separate rotation algorithms. Insertions in AVL Trees

10 AVL Trees10 j k XY Z Consider a valid AVL subtree AVL Insertion: Outside Case h h h

11 AVL Trees11 j k X Y Z Inserting into X destroys the AVL property at node j AVL Insertion: Outside Case h h+1h

12 AVL Trees12 j k X Y Z Do a “right rotation” AVL Insertion: Outside Case h h+1h

13 AVL Trees13 j k X Y Z Do a “right rotation” Single right rotation h h+1h

14 AVL Trees14 j k X Y Z “Right rotation” done! (“Left rotation” is mirror symmetric) Outside Case Completed AVL property has been restored! h h+1 h

15 AVL Trees15 j k XY Z AVL Insertion: Inside Case Consider a valid AVL subtree h h h

16 AVL Trees16 Inserting into Y destroys the AVL property at node j j k X Y Z AVL Insertion: Inside Case Does “right rotation” restore balance? h h+1h

17 AVL Trees17 j k X Y Z “Right rotation” does not restore balance… now k is out of balance AVL Insertion: Inside Case h h+1 h

18 AVL Trees18 Consider the structure of subtree Y… j k X Y Z AVL Insertion: Inside Case h h+1h

19 AVL Trees19 j k X V Z W i Y = node i and subtrees V and W AVL Insertion: Inside Case h h+1h h or h-1

20 AVL Trees20 j k X V Z W i AVL Insertion: Inside Case We will do a left-right “double rotation”...

21 AVL Trees21 j k X V Z W i Double rotation : first rotation left rotation complete

22 AVL Trees22 j k X V Z W i Double rotation : second rotation Now do a right rotation

23 AVL Trees23 j k X V Z W i Double rotation : second rotation right rotation complete Balance has been restored h h h or h-1

24 AVL Trees24 Implementation balance (1,0,-1) key right left No need to keep the height; just the difference in height, i.e. the balance factor; this has to be modified on the path of insertion even if you don’t perform rotations Once you have performed a rotation (single or double) you won’t need to go back up the tree

25 AVL Trees25 Insertion in AVL Trees Insert at the leaf (as for all BST) ›only nodes on the path from insertion point to root node have possibly changed in height ›So after the Insert, go back up to the root node by node, updating heights ›If a new balance factor (the difference h left - h right ) is 2 or –2, adjust tree by rotation around the node

26 AVL Trees26 Insert in AVL trees Insert(T : reference tree pointer, x : element) : { if T = null then {T := new tree; T.data := x; height := 0; return;} case T.data = x : return ; //Duplicate do nothing T.data > x : Insert(T.left, x); if ((height(T.left)- height(T.right)) = 2){ if (T.left.data > x ) then //outside case T = RotatefromLeft (T); else //inside case T = DoubleRotatefromLeft (T);} T.data < x : Insert(T.right, x); code similar to the left case Endcase T.height := max(height(T.left),height(T.right)) +1; return; }

27 AVL Trees27 Example of Insertions in an AVL Tree 1 0 2 20 1030 25 0 35 0 Insert 5, 40

28 AVL Trees28 Example of Insertions in an AVL Tree 1 0 2 20 1030 25 1 35 0 5 0 20 1030 25 1 355 40 0 0 0 1 2 3 Now Insert 45

29 AVL Trees29 Single rotation (outside case) 2 0 3 20 1030 25 1 35 2 5 0 20 1030 25 1 405 0 0 0 1 2 3 45 Imbalance 35 45 00 1 Now Insert 34

30 AVL Trees30 Double rotation (inside case) 3 0 3 20 1030 25 1 40 2 5 0 20 1035 30 1 405 45 0 1 2 3 Imbalance 45 0 1 Insertion of 34 35 34 0 0 1 2534 0

31 AVL Trees31 AVL Tree Deletion Similar but more complex than insertion ›Rotations and double rotations needed to rebalance ›Imbalance may propagate upward so that many rotations may be needed.

32 AVL Trees32 Arguments for AVL trees: 1.Search is O(log N) since AVL trees are always balanced. 2.Insertion and deletions are also O(logn) 3.The height balancing adds no more than a constant factor to the speed of insertion. Arguments against using AVL trees: 1.Difficult to program & debug; more space for balance factor. 2.Asymptotically faster but rebalancing costs time. 3.Most large searches are done in database systems on disk and use other structures (e.g. B-trees). Pros and Cons of AVL Trees

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