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Divide-and-Conquer1 7 2  9 4  2 4 7 9 7  2  2 79  4  4 9 7  72  29  94  4.

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Presentation on theme: "Divide-and-Conquer1 7 2  9 4  2 4 7 9 7  2  2 79  4  4 9 7  72  29  94  4."— Presentation transcript:

1 Divide-and-Conquer1 7 2  9 4  2 4 7 9 7  2  2 79  4  4 9 7  72  29  94  4

2 Divide-and-Conquer2 Outline and Reading Divide-and-conquer paradigm (§5.2) Review Merge-sort (§4.1.1) Recurrence Equations (§5.2.1) Iterative substitution Recursion trees Guess-and-test The master method Integer Multiplication (§5.2.2)

3 Divide-and-Conquer3 Divide-and conquer is a general algorithm design paradigm: Divide: divide the input data S in two or more disjoint subsets S 1, S 2, … Recur: solve the subproblems recursively Conquer: combine the solutions for S 1, S 2, …, into a solution for S The base case for the recursion are subproblems of constant size Analysis can be done using recurrence equations

4 Divide-and-Conquer4 Merge-Sort Review Merge-sort on an input sequence S with n elements consists of three steps: Divide: partition S into two sequences S 1 and S 2 of about n  2 elements each Recur: recursively sort S 1 and S 2 Conquer: merge S 1 and S 2 into a unique sorted sequence Algorithm mergeSort(S, C) Input sequence S with n elements, comparator C Output sequence S sorted according to C if S.size() > 1 (S 1, S 2 )  partition(S, n/2) mergeSort(S 1, C) mergeSort(S 2, C) S  merge(S 1, S 2 )

5 Divide-and-Conquer5 Recurrence Equation Analysis The conquer step of merge-sort consists of merging two sorted sequences, each with n  2 elements and implemented by means of a doubly linked list, takes at most bn steps, for some constant b. Likewise, the basis case ( n < 2) will take at b most steps. Therefore, if we let T(n) denote the running time of merge-sort: We can therefore analyze the running time of merge-sort by finding a closed form solution to the above equation. That is, a solution that has T(n) only on the left-hand side.

6 Divide-and-Conquer6 Iterative Substitution In the iterative substitution, or “plug-and-chug,” technique, we iteratively apply the recurrence equation to itself and see if we can find a pattern: Note that base, T(n)=b, case occurs when 2 i =n. That is, i = log n. So, Thus, T(n) is O(n log n).

7 Divide-and-Conquer7 The Recursion Tree Draw the recursion tree for the recurrence relation and look for a pattern: depthT’ssize 01n 12 n2n2 i2i2i n2in2i ……… time bn … Total time = bn + bn log n (last level plus all previous levels)

8 Divide-and-Conquer8 Guess-and-Test Method In the guess-and-test method, we guess a closed form solution and then try to prove it is true by induction: Guess: T(n) < cn log n. Wrong: we cannot make this last line be less than cn log n

9 Divide-and-Conquer9 Guess-and-Test Method, Part 2 Recall the recurrence equation: Guess #2: T(n) < cn log 2 n. if c > b. So, T(n) is O(n log 2 n). In general, to use this method, you need to have a good guess and you need to be good at induction proofs.

10 Divide-and-Conquer10 Master Method Many divide-and-conquer recurrence equations have the form: The Master Theorem:

11 Divide-and-Conquer11 Master Method, Example 1 The form: The Master Theorem: Example: Solution: log b a=2, so case 1 says T(n) is O(n 2 ).

12 Divide-and-Conquer12 Master Method, Example 2 The form: The Master Theorem: Example: Solution: log b a=1, so case 2 says T(n) is O(n log 2 n).

13 Divide-and-Conquer13 Master Method, Example 3 The form: The Master Theorem: Example: Solution: log b a=0, so case 3 says T(n) is O(n log n).

14 Divide-and-Conquer14 Master Method, Example 4 The form: The Master Theorem: Example: Solution: log b a=3, so case 1 says T(n) is O(n 3 ).

15 Divide-and-Conquer15 Master Method, Example 5 The form: The Master Theorem: Example: Solution: log b a=2, so case 3 says T(n) is O(n 3 ).

16 Divide-and-Conquer16 Master Method, Example 6 The form: The Master Theorem: Example: Solution: log b a=0, so case 2 says T(n) is O(log n). (binary search)

17 Divide-and-Conquer17 Master Method, Example 7 The form: The Master Theorem: Example: Solution: log b a=1, so case 1 says T(n) is O(n). (heap construction)

18 Divide-and-Conquer18 Iterative “Proof” of the Master Theorem Using iterative substitution, let us see if we can find a pattern: We then distinguish the three cases as The first term is dominant Each part of the summation is equally dominant The summation is a geometric series

19 Divide-and-Conquer19 Integer Multiplication Algorithm: Multiply two n-bit integers I and J. Divide step: Split I and J into high-order and low-order bits We can then define I*J by multiplying the parts and adding: So, T(n) = 4T(n/2) + n, which implies T(n) is O(n 2 ). But that is no better than the algorithm we learned in grade school.

20 Divide-and-Conquer20 An Improved Integer Multiplication Algorithm Algorithm: Multiply two n-bit integers I and J. Divide step: Split I and J into high-order and low-order bits Observe that there is a different way to multiply parts: So, T(n) = 3T(n/2) + n, which implies T(n) is O(n log 2 3 ), by the Master Theorem. Thus, T(n) is O(n 1.585 ).

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