Analysis of Algorithms CS 477/677

1. Analysis of AlgorithmsCS 477/677 Instructor: Monica Nicolescu

2. A 0 1 2 3 4 5 C 2 2 4 7 7 8 1 1 2 2 3 3 4 4 5 5 6 6 7 7 8 8 2 0 5 0 2 3 2 0 2 3 3 3 3 0 5 3 B Counting Sort • Assumption: • The elements to be sorted are integers in the range 0 to k • Idea: • Determine for each input element x, the number of elements smaller than x • Place element x into its correct position in the output array CS 477/677

3. Radix Sort • Considers keys as numbers in a base-R number • A d-digit number will occupy a field of d columns • Sorting looks at one column at a time • For a d digit number, sort the least significant digit first • Continue sorting on the next least significant digit, until all digits have been sorted • Requires only d passes through the list CS 477/677

4. Bucket Sort • Assumption: • the input is generated by a random process that distributes elements uniformly over [0, 1) • Idea: • Divide [0, 1) into n equal-sized buckets • Distribute the n input values into the buckets • Sort each bucket • Go through the buckets in order, listing elements in each one • Input: A[1 . . n], where 0 ≤ A[i] < 1 for all i • Output: elements ai sorted • Auxiliary array: B[0 . . n - 1] of linked lists, each list initially empty CS 477/677

5. BUCKET-SORT Alg.: BUCKET-SORT(A, n) for i ← 1to n do insert A[i] into list B[nA[i]] for i ← 0to n - 1 do sort list B[i] with insertion sort concatenate lists B[0], B[1], . . . , B[n -1] together in order return the concatenated lists CS 477/677

6. / / .12 / .39 / .26 .68 / .17 .78 .23 / .21 .72 / .94 / / / Example - Bucket Sort 1 0 2 1 3 2 4 3 5 4 6 5 7 6 8 7 9 8 10 9 CS 477/677

7. / / .78 .23 .68 .78 / .17 / .72 .26 / .39 .94 / .72 .39 / .21 .12 .17 .12 .23 .94 / .26 .21 .68 / / / Example - Bucket Sort 0 1 2 3 4 5 6 7 Concatenate the lists from 0 to n – 1 together, in order 8 9 CS 477/677

8. Correctness of Bucket Sort • Consider two elements A[i], A[ j] • Assume without loss of generality that A[i] ≤ A[j] • Then nA[i] ≤ nA[j] • A[i] belongs to the same group as A[j] or to a group with a lower index than that of A[j] • If A[i], A[j] belong to the same bucket: • insertion sort puts them in the proper order • If A[i], A[j] are put in different buckets: • concatenation of the lists puts them in the proper order CS 477/677

9. Analysis of Bucket Sort Alg.: BUCKET-SORT(A, n) for i ← 1to n do insert A[i] into list B[nA[i]] for i ← 0to n - 1 do sort list B[i] with insertion sort concatenate lists B[0], B[1], . . . , B[n -1] together in order return the concatenated lists O(n) (n) O(n) (n) CS 477/677

10. Conclusion • Any comparison sort will take at least nlgn to sort an array of n numbers • We can achieve a better running time for sorting if we can make certain assumptions on the input data: • Counting sort: each of the n input elements is an integer in the range 0 to k • Radix sort: the elements in the input are integers represented with d digits • Bucket sort: the numbers in the input are uniformly distributed over the interval [0, 1) CS 477/677

11. A Job Scheduling Application • Job scheduling • The key is the priority of the jobs in the queue • The job with the highest priority needs to be executed next • Operations • Insert, remove maximum • Data structures • Priority queues • Ordered array/list, unordered array/list CS 477/677

12. Example CS 477/677

13. PQ Implementations & Cost Worst-case asymptotic costs for a PQ with N items Insert Remove max ordered array N 1 ordered list N 1 unordered array 1 N unordered list 1 N Can we implement both operations efficiently? CS 477/677

14. Background on Trees • Def:Binary tree = structure composed of a finite set of nodes that either: • Contains no nodes, or • Is composed of three disjoint sets of nodes: a root node, a left subtree and a right subtree root 4 Right subtree Left subtree 1 3 2 16 9 10 14 8 CS 477/677

15. 4 4 1 3 1 3 2 16 9 10 2 16 9 10 14 8 7 12 Complete binary tree Full binary tree Special Types of Trees • Def:Full binary tree = a binary tree in which each node is either a leaf or has degree exactly 2. • Def:Complete binary tree = a binary tree in which all leaves have the same depth and all internal nodes have degree 2. CS 477/677

16. The Heap Data Structure • Def:A heap is a nearly complete binary tree with the following two properties: • Structural property: all levels are full, except possibly the last one, which is filled from left to right • Order (heap) property: for any node x Parent(x) ≥ x 8 It doesn’t matter that 4 in level 1 is smaller than 5 in level 2 7 4 5 2 Heap CS 477/677

17. Definitions • Height of a node = the number of edges on a longest simple path from the node down to a leaf • Depth of a node = the length of a path from the root to the node • Height of tree = height of root node = lgn, for a heap of n elements Height of root = 3 4 1 3 Height of (2)= 1 Depth of (10)= 2 2 16 9 10 14 8 CS 477/677

18. Array Representation of Heaps • A heap can be stored as an array A. • Root of tree is A[1] • Left child of A[i] = A[2i] • Right child of A[i] = A[2i + 1] • Parent of A[i] = A[ i/2 ] • Heapsize[A] ≤ length[A] • The elements in the subarray A[(n/2+1) .. n] are leaves • The root is the maximum element of the heap A heap is a binary tree that is filled in order CS 477/677

19. Heap Types • Max-heaps (largest element at root), have the max-heap property: • for all nodes i, excluding the root: A[PARENT(i)] ≥ A[i] • Min-heaps (smallest element at root), have the min-heap property: • for all nodes i, excluding the root: A[PARENT(i)] ≤ A[i] CS 477/677

20. Operations on Heaps • Maintain the max-heap property • MAX-HEAPIFY • Create a max-heap from an unordered array • BUILD-MAX-HEAP • Sort an array in place • HEAPSORT • Priority queue operations CS 477/677

21. Operations on Priority Queues • Max-priority queues support the following operations: • INSERT(S, x): inserts element x into set S • EXTRACT-MAX(S): removes and returns element of S with largest key • MAXIMUM(S): returns element of S with largest key • INCREASE-KEY(S, x, k): increases value of element x’s key to k (Assume k ≥ x’s current key value) CS 477/677

22. Maintaining the Heap Property • Suppose a node is smaller than a child • Left and Right subtrees of i are max-heaps • Invariant: • the heap condition is violated only at that node • To eliminate the violation: • Exchange with larger child • Move down the tree • Continue until node is not smaller than children CS 477/677

23. Maintaining the Heap Property Alg:MAX-HEAPIFY(A, i, n) • l ← LEFT(i) • r ← RIGHT(i) • ifl ≤ n and A[l] > A[i] • thenlargest ←l • elselargest ←i • ifr ≤ n and A[r] > A[largest] • thenlargest ←r • iflargest  i • then exchange A[i] ↔ A[largest] • MAX-HEAPIFY(A, largest, n) • Assumptions: • Left and Right subtrees of i are max-heaps • A[i] may be smaller than its children CS 477/677

24. A[2] violates the heap property A[4] violates the heap property Heap property restored Example MAX-HEAPIFY(A, 2, 10) A[2]  A[4] A[4]  A[9] CS 477/677

25. MAX-HEAPIFY Running Time • Intuitively: • A heap is an almost complete binary tree  must process O(lgn) levels, with constant work at each level • Running time of MAX-HEAPIFY is O(lgn) • Can be written in terms of the height of the heap, as being O(h) • Since the height of the heap is lgn CS 477/677

26. Alg:BUILD-MAX-HEAP(A) n = length[A] fori ← n/2downto1 do MAX-HEAPIFY(A, i, n) Convert an array A[1 … n] into a max-heap (n = length[A]) The elements in the subarray A[(n/2+1) .. n] are leaves Apply MAX-HEAPIFY on elements between 1 and n/2 1 4 2 3 1 3 4 5 6 7 2 16 9 10 8 9 10 14 8 7 Building a Heap A: CS 477/677

27. 1 1 1 1 4 16 4 4 2 2 3 3 2 3 2 3 14 1 10 3 1 3 1 3 4 4 5 5 6 6 7 7 4 5 6 7 4 5 6 7 8 2 16 7 9 9 10 3 2 16 9 10 14 16 9 10 8 8 9 9 10 10 8 9 10 8 9 10 14 2 8 4 1 7 14 8 7 2 8 7 1 1 4 4 2 3 2 3 1 10 16 10 4 5 6 7 4 5 6 7 14 16 9 3 14 7 9 3 8 9 10 8 9 10 2 8 7 2 8 1 Example: A i = 5 i = 4 i = 3 i = 2 i = 1 CS 477/677

28. 1 4 2 3 1 3 4 5 6 7 2 16 9 10 8 9 10 14 8 7 Correctness of BUILD-MAX-HEAP • Loop invariant: • At the start of each iteration of the for loop, each node i + 1, i + 2,…, n is the root of a max-heap • Initialization: • i = n/2: Nodes n/2+1, n/2+2, …, n are leaves  they are the root of trivial max-heaps CS 477/677

29. 1 4 2 3 1 3 4 5 6 7 2 16 9 10 8 9 10 14 8 7 Correctness of BUILD-MAX-HEAP • Maintenance: • MAX-HEAPIFY makes node i a max-heap root and preserves the property that nodes i + 1, i + 2, …, n are roots of max-heaps • Decrementing i in the for loop reestablishes the loop invariant • Termination: • i = 0  each node 1, 2, …, n is the root of a max-heap (by the loop invariant) CS 477/677

30. Running Time of BUILD MAX HEAP  Running time: O(nlgn) • This is not an asymptotically tight upper bound Alg:BUILD-MAX-HEAP(A) • n = length[A] • fori ← n/2downto1 • do MAX-HEAPIFY(A, i, n) O(n) O(lgn) CS 477/677

31. Running Time of BUILD MAX HEAP • HEAPIFY takes O(h) the cost of HEAPIFY on a node i is proportional to the height of the node i in the tree Height Level No. of nodes h0 = 3 (lgn) i = 0 20 i = 1 h1 = 2 21 i = 2 h2 = 1 22 h3 = 0 i = 3 (lgn) 23 hi = h – i height of the heap rooted at level i ni = 2i number of nodes at level i CS 477/677

32. Readings • Chapter 6 • Chapter 8 CS 477/677