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CSE373: Data Structures & Algorithms Lecture 7: AVL Trees Linda Shapiro Winter 2015.

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1 CSE373: Data Structures & Algorithms Lecture 7: AVL Trees Linda Shapiro Winter 2015

2 Announcements HW2 due TODAY TA sessions this week – Thursday: Binary Search Trees and AVL Trees Last lecture: Binary Search Trees Today… AVL Trees Winter 2015CSE373: Data Structures & Algorithms2

3 Review: Binary Search Tree (BST) 4 121062 115 8 14 13 79 Structure property (binary tree) – Each node has  2 children – Result: keeps operations simple Order property – All keys in left subtree smaller than node’s key – All keys in right subtree larger than node’s key – Result: easy to find any given key Winter 20153CSE373: Data Structures & Algorithms

4 BST: Efficiency of Operations? Winter 2015CSE373: Data Structures & Algorithms4 Problem: operations may be inefficient if BST is unbalanced. Find, insert, delete – O(n) in the worst case BuildTree – O(n 2 ) in the worst case

5 Observation BST: the shallower the better! Solution: Require and maintain a Balance Condition that 1.Ensures depth is always O( log n) – strong enough! 2.Is efficient to maintain – not too strong! Winter 20155CSE373: Data Structures & Algorithms How can we make a BST efficient? When we build the tree, make sure it’s balanced. BUT…Balancing a tree only at build time is insufficient because sequences of operations can eventually transform our carefully balanced tree into the dreaded list  So, we also need to also keep the tree balanced as we perform operations.

6 Potential Balance Conditions 1.Left and right subtrees of the root have equal number of nodes 2.Left and right subtrees of the root have equal height Too weak! Height mismatch example: Too weak! Double chain example: Winter 20156CSE373: Data Structures & Algorithms

7 Potential Balance Conditions 3.Left and right subtrees of every node have equal number of nodes 4.Left and right subtrees of every node have equal height Too strong! Only perfect trees (2 n – 1 nodes) Too strong! Only perfect trees (2 n – 1 nodes) Winter 20157CSE373: Data Structures & Algorithms

8 8 The AVL Balance Condition Left and right subtrees of every node have heights differing by at most 1 Definition: balance(node) = height(node.left) – height(node.right) AVL property: for every node x, –1  balance(x)  1 Ensures small depth –This is because an AVL tree of height h must have a number of nodes exponential in h Thus height must be log(number of nodes). Efficient to maintain –Using single and double rotations Winter 2015CSE373: Data Structures & Algorithms

9 9 The AVL Tree Data Structure An AVL tree is a self-balancing binary search tree. Structural properties 1.Binary tree property (same as BST) 2.Order property (same as for BST) 1.Balance property: balance of every node is between -1 and 1 Result: Worst-case depth is O(log n) Named after inventors Adelson-Velskii and Landis (AVL) –First invented in 1962 Winter 2015CSE373: Data Structures & Algorithms

10 11 1 84 6 10 12 7 0 0 0 0 1 1 2 3 Is this an AVL tree? Winter 2015CSE373: Data Structures & Algorithms10 Yes! Because the left and right subtrees of every node have heights differing by at most 1

11 3 117 1 84 6 2 5 0 000 1 1 2 3 4 Is this an AVL tree? Winter 2015CSE373: Data Structures & Algorithms11 Nope! The left and right subtrees of some nodes (e.g. 1, 4, 6) have heights that differ by more than 1

12 What do AVL trees give us? If we have an AVL tree, then the number of nodes is an exponential function of the height. Thus the height is a log function of the number of nodes! And thus find is O( log n) But as we insert and delete elements, we need to: 1.Track balance 2.Detect imbalance 3.Restore balance Winter 201512CSE373: Data Structures & Algorithms

13 An AVL Tree 20 92 15 5 10 30 177 0 0 0 011 22 3 Track height at all times! Winter 2015CSE373: Data Structures & Algorithms13 … 3 value height children 10 key Node object

14 AVL tree operations AVL find : –Same as BST find AVL insert : –First BST insert, then check balance and potentially “fix” the AVL tree –Four different imbalance cases AVL delete : –The “easy way” is lazy deletion –Otherwise, do the deletion and then check for several imbalance cases (we will skip this) Winter 2015CSE373: Data Structures & Algorithms14

15 Insert: detect potential imbalance 1.Insert the new node as in a BST (a new leaf) 2.For each node on the path from the root to the new leaf, the insertion may (or may not) have changed the node’s height 3.So after insertion in a subtree, detect height imbalance and perform a rotation to restore balance at that node All the action is in defining the correct rotations to restore balance Fact that an implementation can ignore: –There must be a deepest element that is imbalanced after the insert (all descendants still balanced) –After rebalancing this deepest node, every node is balanced –So at most one node needs to be rebalanced Winter 201515CSE373: Data Structures & Algorithms

16 Case #1: Example Winter 201516CSE373: Data Structures & Algorithms Insert(6) Insert(3) Insert(1) Third insertion violates balance property happens to be at the root What is the only way to fix this? 6 3 1 2 1 0 6 3 1 0 6 0 6 3 1 0 1 0

17 Fix: Apply “Single Rotation” Single rotation: The basic operation we’ll use to rebalance –Move child of unbalanced node into parent position –Parent becomes the “other” child (always okay in a BST!) –Other subtrees move in only way BST allows (next slide) Winter 201517CSE373: Data Structures & Algorithms 3 16 0 0 1 6 3 0 1 2 AVL Property violated at node 6 Child’s new-height = old-height-before-insert 1

18 The example generalized: Left of Left Insertion into left-left grandchild causes an imbalance –1 of 4 possible imbalance causes (other 3 coming up!) Creates an imbalance in the AVL tree (specifically a is imbalanced) Winter 201518CSE373: Data Structures & Algorithms a Z Y b X h h h h+1 h+2 a Z Y b X h+1 h h h+2 h+3

19 Winter 2015CSE373: Data Structures & Algorithms19

20 Winter 2015CSE373: Data Structures & Algorithms20

21 The general left-left case So we rotate at a –Move left child of unbalanced node into parent position –Parent becomes the right child –Other sub-trees move in the only way BST allows: using BST facts: X < b < Y < a < Z Winter 201521CSE373: Data Structures & Algorithms A single rotation restores balance at the node –To same height as before insertion, so ancestors now balanced a Z Y b X h+1 h h h+2 h+3 b ZY a h+1 h h h+2 X

22 Another example: insert(16) Winter 201522CSE373: Data Structures & Algorithms 10 4 22 8 15 3 6 19 1720 24 16 10 4 8 15 3 6 19 17 2016 22 24

23 The general right-right case Mirror image to left-left case, so you rotate the other way –Exact same concept, but needs different code Winter 201523CSE373: Data Structures & Algorithms a ZY X h h h+1 h+3 b h+2 b Z Y a X h h h+1 h+2

24 Two cases to go Unfortunately, single rotations are not enough for insertions in the left-right subtree or the right-left subtree Simple example: insert (1), insert (6), insert (3) –First wrong idea: single rotation like we did for left-left Winter 201524CSE373: Data Structures & Algorithms 3 6 1 0 1 2 6 1 3 1 00 Violates order property!

25 Two cases to go Unfortunately, single rotations are not enough for insertions in the left-right subtree or the right-left subtree Simple example: insert (1), insert (6), insert (3) –Second wrong idea: single rotation on the child of the unbalanced node Winter 201525CSE373: Data Structures & Algorithms 3 6 1 0 1 2 6 3 1 0 1 2 Still unbalanced!

26 Sometimes two wrongs make a right First idea violated the order property Second idea didn’t fix balance But if we do both single rotations, starting with the second, it works! (And not just for this example.) Double rotation: 1.Rotate problematic child and grandchild 2.Then rotate between self and new child Winter 201526CSE373: Data Structures & Algorithms 3 6 1 0 1 2 6 3 1 0 1 2 1 0 0 1 3 6

27 The general right-left case Winter 201527CSE373: Data Structures & Algorithms a X b c h-1 h h h V U h+1 h+2 h+3 Z a X c h-1 h+1 h h V U h+2 h+3 Z b h c X h-1 h+1 h V U h+2 Z b h a h

28 Comments Like in the left-left and right-right cases, the height of the subtree after rebalancing is the same as before the insert –So no ancestor in the tree will need rebalancing Does not have to be implemented as two rotations; can just do: Winter 201528CSE373: Data Structures & Algorithms a X b c h-1 h h h V U h+1 h+2 h+3 Z c X h-1 h+ 1 h V U h+2 Z b h a h Easier to remember than you may think: Move c to grandparent’s position Put a, b, X, U, V, and Z in the only legal positions for a BST

29 The last case: left-right Mirror image of right-left –Again, no new concepts, only new code to write Winter 201529CSE373: Data Structures & Algorithms a h-1 h h h V U h+1 h+2 h+3 Z X b c c X h-1 h+ 1 h V U h+2 Z a h b h

30 Insert, summarized Insert as in a BST Check back up path for imbalance, which will be 1 of 4 cases: –Node’s left-left grandchild is too tall –Node’s left-right grandchild is too tall –Node’s right-left grandchild is too tall –Node’s right-right grandchild is too tall Only one case occurs because tree was balanced before insert After the appropriate single or double rotation, the smallest- unbalanced subtree has the same height as before the insertion –So all ancestors are now balanced Winter 201530CSE373: Data Structures & Algorithms

31 Example 20 92 15 5 10 30 177 0 0 0 011 22 3 Winter 2015CSE373: Data Structures & Algorithms31

32 Insert a 6 20 92 15 5 10 30 177 0 0 0 01 1 2 2 3 Winter 2015CSE373: Data Structures & Algorithms32 6 4 What’s the deepest node that is unbalanced? What’s the case? What do we do? left-left

33 Insert a 6 20 72 15 5 10 30 176 0 0 0 01 0 1 2 2 Winter 2015CSE373: Data Structures & Algorithms33 9 3

34 Insert a 13 20 72 15 5 10 30 17 6 0 0 0 01 0 1 2 2 Winter 2015CSE373: Data Structures & Algorithms34 9 3 13

35 Insert a 14 20 72 15 5 10 30 17 6 0 0 0 02 0 1 3 2 Winter 2015CSE373: Data Structures & Algorithms35 9 4 13 14 0 1 What is the deepest unbalanced node?

36 Insert a 14 20 72 15 5 10 30 17 6 0 0 0 02 0 1 3 2 Winter 2015CSE373: Data Structures & Algorithms36 9 4 13 14 0 1 What is the deepest unbalanced node? Which of the four cases is this? Still left-left! Single rotation

37 Insert a 14 20 72 15 5 10 30 17 6 0 0 0 1 2 0 1 2 Winter 2015CSE373: Data Structures & Algorithms37 9 3 13 14 0 1 0

38 Now efficiency Worst-case complexity of find : O( log n) –Tree is balanced Worst-case complexity of insert : O( log n) –Tree starts balanced –A rotation is O(1) and there’s an O( log n) path to root –Tree ends balanced Worst-case complexity of buildTree : O(n log n) Takes some more rotation action to handle delete … Winter 201538CSE373: Data Structures & Algorithms

39 Pros and Cons of AVL Trees Winter 2015CSE373: Data Structures & Algorithms39 Arguments for AVL trees: 1.All operations logarithmic worst-case because trees are always balanced 2.Height balancing adds no more than a constant factor to the speed of insert and delete Arguments against AVL trees: 1.More difficult to program & debug [but done once in a library!] 2.More space for height field 3.Asymptotically faster but rebalancing takes a little time 4.If amortized (later) logarithmic time is enough, use splay trees (also in the text)

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