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Tirgul 6 B-Trees – Another kind of balanced trees.

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Presentation on theme: "Tirgul 6 B-Trees – Another kind of balanced trees."— Presentation transcript:

1 Tirgul 6 B-Trees – Another kind of balanced trees

2 Motivation Primary memory (RAM) : very fast, but costly Secondary storage (disk) : very cheap, but slow Problem: a large D.B. must reside partially on disk. But disk operations are very slow. Solution: take advantage of important disk property -Basic read/write unit is a page (2-4 Kb) - can’t read/write less. Thus when analyzing D.B. performance, we consider two different measures: CPU time and number of times we need to access the disk. Besides, B-trees are an interesting type of balanced trees...

3 B-Trees B-Tree: a balanced search tree whose nodes can have many children: A node x contains n[x] keys, and has n[x]+1 children (c 1 [x], c 2 [x], …, c n[x]+1 [x]). The keys in each node are ordered, and relate to their left and right sub-trees like regular search trees: if k i is any key stored in the sub-tree rooted at c i [x], then: All leaves have the same depth h (the tree’s height) There is a fixed integer t (the minimum degree) : –Every node (besides the root) has at least t-1 keys (i.e. t children) –Every node can contain at most 2t-1 keys (2t children).

4 Example 50 2510898365733934827086856154939022201712 t=3

5 B-Trees and disk access (last time...) Each node contains as many keys as possible without being larger than a single page on disk. Whenever we need to access a node – load it from the disk (one read operation), after changing a node – rewrite it to the disk. For example, say each node contains 1000 keys – then the root has 1001 children, each of which also has 1001 children. Thus with just 2 disk accesses we are able to access ~1000 3 records. Operations are designed to work in one pass from the root to the leaves – we do not need to backtrack our steps. This further reduces the number of disk accesses we make.

6 The height of a B-Tree Theorem: If n  1, then for any B-tree of height h with n keys and minimum degree t  2: h  log t ( (n+1) / 2 ) Proof : Each child of the root has at least t children, each of them also has at least t children, and so on. Thus in every sub-tree of the root there are at least nodes. Each of them contains at least t-1 keys. The root contains at least one key and has at least two children, so we have:

7 B-Tree Search Search is done in the regular way: In each node, we find the sub-tree in which our value might be, and recursively find it there. Performance : O(th) = O(tlog t n) - total run-time, out of which: O(h) = O(log t n) - disk access operations

8 B-Tree Split Used for insertion. This operation verifies that a node will have less than 2t-1 keys. What we do is split the node into two nodes, each with t-1 keys. The extra key goes into the node’s parent (We assume the parent is not full) To split a node x (look at the next slide for illustration), take key t [x] (notice it is the median key). All smaller keys (exactly t-1 of them) form one new (legal) node, the same with all larger keys. key t [x] goes into x’s parent. If the node we split is the root, then a new root is created. This new root contains only one key.

9 B-tree split xy m t-1 keys...... xym t-1 keys...... (parent) (full node) Notice that the parent has many other sub-trees that don’t change.

10 Example 50 2510 8983659596 89502510 83659596 A full node (t=3)

11 B-Tree Insert We insert a key only to a leaf. We start from the root and go down to the appropriate leaf. On the way, before going down to the next node, we check if it is full. If so, we split it (its father is non-full because we checked this before going down to the father). When we reach the right leaf, we know that the leaf is not full, so we can simply insert the new value to the leaf. Notice that we may need to split the root, if it is full. In this case, the tree’s height increases (but the tree remains completely balanced!). That’s why we say that a B-tree grows from the root, in contrast to most of the trees, who grow from the leaves...

12 Example 10733439 (I) Inserting 3,7,34,10,39 10 73253934 (II) Inserting 25 splits the root 10 732539342040 (III) Inserting 40 and 20 3410734039 252017 (IV) Inserting 17 splits the right leaf We start with an empty tree (t=3)

13 B-Tree Insert (cont.) Performance: –Split: three disk accesses (to write the 2 new nodes, and the parent) O(t) - total run time –Insert: O(h) - disk accesses O(tlog t n) - total run time Requires O(1) pages in main memory.

14 B-Tree Delete Delete is a bit more complicated... The basic idea – when we go down the tree, we make sure the next node has at least t keys, so we will be able to delete a value from a leaf. For this we use merge - the inverse of split. If we have two children with t-1 keys and a parent with at least t keys, we take one key from the parent and merge it with the two children to become a single node. We also use a rotation - move a value from one child who has at least t keys to another (see next slides).

15 Merge xy m t-1 keys...... xym t-1 keys...... parent with at least t keys Notice that the parent has many other sub-trees that don’t change.

16 (left) rotation m t-1 keys X #keys >= t-1 Rotation is done when we have two consecutive siblings, one with exactly t-1 keys and one with at least t keys. Similarly we can do right rotation. T X t-1 keys m T #keys >= t-1

17 B-Tree Delete (1) For each node x on the way to k (x is internal, and doesn ’ t contain k), determine the sub-tree that should contain k (whose root is c i [x]), and, If c i [x] has at least t keys, simply delete k from it by recursion. If c i [x] has only t-1 keys but has an adjacent sibling with t keys, add c i [x] an extra key by left/right rotation. Now recurse to c i [x] Otherwise, merge c i [x] and one of its adjacent siblings (note that x itself has at least t keys). Continue deletion from the merged node. Similarly to insertion, the tree height decreases (only) when we perform a merge operation, the parent is the root, and it contains only one value.

18 B-Tree Delete (2) If we want to delete a key k and we found the node x that contains k If x is a leaf – simply remove k from x (we assume x has at least t keys, which we verify in the descent, see also below). If x is an internal node: –Let y be the left child of k. If y has at least t keys, then recursively delete the largest key from y (call it k ’ ) and replace k with k ’ in x. –Otherwise, do this for the right child, z, of k. –If both y and z have only t-1 keys, merge y, z, and k. Recursively delete k from the merged node (notice that the new node has 2t-1 keys).

19 Performance of delete operation O(h) disk accesses O(th)=O(tlog t n) total run time The advantage - only one pass down the tree!

20 Example 3410734039 252017 (I) Deleting 39 causes a right rotation 2510734034 2017 Start: 10 73 25403417 (II) Deleting 20 causes a merge 17 73 344025 (III) Deleting 10 17 73 3425 (IV) Deleting 40 725173 (V) Deleting 34 causes a merge and the tree shrinks

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