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Richard Anderson Lecture 12 Recurrences and Divide and Conquer

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1 Richard Anderson Lecture 12 Recurrences and Divide and Conquer
CSE 421 Algorithms Richard Anderson Lecture 12 Recurrences and Divide and Conquer

2 Divide and Conquer

3 Recurrence Examples T(n) = 2 T(n/2) + cn T(n) = T(n/2) + cn
O(n log n) T(n) = T(n/2) + cn O(n) More useful facts: logkn = log2n / log2k k log n = n log k

4 T(n) = aT(n/b) + f(n)

5 Recursive Matrix Multiplication
Multiply 2 x 2 Matrices: | r s | | a b| |e g| | t u| | c d| | f h| r = ae + bf s = ag + bh t = ce + df u = cg + dh A N x N matrix can be viewed as a 2 x 2 matrix with entries that are (N/2) x (N/2) matrices. The recursive matrix multiplication algorithm recursively multiplies the (N/2) x (N/2) matrices and combines them using the equations for multiplying 2 x 2 matrices =

6 Recursive Matrix Multiplication
How many recursive calls are made at each level? How much work in combining the results? What is the recurrence?

7 What is the run time for the recursive Matrix Multiplication Algorithm?
Recurrence:

8 T(n) = 4T(n/2) + cn

9 T(n) = 2T(n/2) + n2

10 T(n) = 2T(n/2) + n1/2

11 Recurrences Three basic behaviors Dominated by initial case
Dominated by base case All cases equal – we care about the depth

12 Solve by unrolling T(n) = n + 5T(n/2)
Answer: nlog(5/2)

13 What you really need to know about recurrences
Work per level changes geometrically with the level Geometrically increasing (x > 1) The bottom level wins Geometrically decreasing (x < 1) The top level wins Balanced (x = 1) Equal contribution

14 Classify the following recurrences (Increasing, Decreasing, Balanced)
T(n) = n + 5T(n/8) T(n) = n + 9T(n/8) T(n) = n2 + 4T(n/2) T(n) = n3 + 7T(n/2) T(n) = n1/2 + 3T(n/4)

15 Strassen’s Algorithm Multiply 2 x 2 Matrices: | r s | | a b| |e g|
| t u| | c d| | f h| Where: p1 = (b + d)(f + g) p2= (c + d)e p3= a(g – h) p4= d(f – e) p5= (a – b)h p6= (c – d)(e + g) p7= (b – d)(f + h) = r = p1 + p4 – p5 + p7 s = p3 + p5 t = p2 + p5 u = p1 + p3 – p2 + p7

16 Recurrence for Strassen’s Algorithms
T(n) = 7 T(n/2) + cn2 What is the runtime?

17 BFPRT Recurrence T(n) <= T(3n/4) + T(n/5) + 20 n
What bound do you expect?

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