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Week 2 CS 361: Advanced Data Structures and Algorithms

Week 2 CS 361: Advanced Data Structures and Algorithms. Introduction to Algorithms. Class Overview. Start thinking about analyzing a program or algorithm. Understand algorithm efficiency and running-time complexity . Analysis of an algorithm using Big-O notation.

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Week 2 CS 361: Advanced Data Structures and Algorithms

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  1. Week 2CS 361: Advanced Data Structures and Algorithms Introduction to Algorithms

  2. Class Overview • Start thinking about analyzing a program or algorithm. • Understand algorithm efficiency and running-time complexity. • Analysis of an algorithm using Big-O notation. Which Cost More to Feed?

  3. Algorithm Efficiency • There are often many approaches (algorithms) to solve a problem. • How do we choose between them? • There are two (sometimes conflicting) goals at the heart of computer program design. To design an algorithm that: • is easy to understand, code, debug. • makes efficient use of the resources. • Goal (1) is the concern of Software Engineering. • Goal (2) is the concern of data structures and algorithm analysis. • When goal (2) is important, • how do we measure an algorithm’s cost?

  4. Estimation Techniques • Known as “back of the envelope” or “back of the napkin” calculation • Determine the major parameters that effect the problem. • Derive an equation that relates the parameters to the problem. • Select values for the parameters, and apply the equation to yield and estimated solution. Essentially, you need to understand the problem

  5. Estimation Example • How many library bookcases does it take to store books totaling one million pages? • Estimate: • Pages/inch • Shelf/Feet • Shelves/bookcase

  6. Best, Worst, Average Cases • Not all inputs of a given size take the same time to run. • Sequential search for K in an array of n integers: • Begin at first element in array and look at each element in turn until K is found • Best case: • Worst case: • Average case:

  7. Time Analysis • Provides upper and lower bounds of running time. • Different types of analysis: • - Worst case • - Best case • - Average case

  8. Worst Case • Provides an upper bound on running time. • An absolute guarantee that the algorithm would not run longer, no matter what the inputs are.

  9. Best Case • Provides a lower bound on running time. • Inputis the one for which the algorithm runs the fastest.

  10. Average Case • Provides an estimate of “average” running time. • Assumes that the input is random. • Useful when best/worst cases do not happen very often • i.e., few input cases lead to best/worst cases.

  11. Which Analysis to Use? • While average time appears to be the fairest measure, • It may be difficult to determine. • For example, algorithms that are designed to operate on strings of text. • Why is the worst case time important? • In some situations it may be necessary to use a pessimistic analysis in order to guarantee safety. • Recall the “bookcase” problem.

  12. How to Measure Efficiency? • Critical resources: • Time, memory, programmer effort, user effort • Factors affecting running time: • For most algorithms, running time depends on “size” of the input. • Running timeis expressed as T(n)for some function T on input size n. 12

  13. How do we analyze an algorithm? • Need to define objective measures. (1)Compare execution times? Not good: times are specific to a particular machine. (2)Count the number of statements? Not good: number of statements varies with programming language and style.

  14. How do we analyze an algorithm? (cont.) (3) Express running time T as a function of problem size n (i.e., T=f(n)) Asymptotic Algorithm Analysis • Given two algorithms having running times f(n) and g(n),find which functions grows faster? • Compare “rates of growth”of f(n) and g(n). • Such an analysis is independent of machine time, programming style, etc.

  15. Understanding Rate of Growth • Consider the example of feeding elephants and goldfish: Total Cost: (cost_of_feeding_elephants) + (cost_of_feeding_goldfish) Approximation: Total Cost ~ cost_of_feeding_elephants

  16. Understanding Rate of Growth (cont’d) • The low order terms of a function are relatively insignificant for largen n4 + 100n2 + 10n + 50 Approximation: n4 • Highest order termdetermines rate of growth!

  17. Visualizing Orders of Growth • On a graph, as you go to the right, a faster growing function eventually becomes larger...

  18. Growth Rate Graph

  19. Common orders of magnitude

  20. Orders of Magnitude

  21. Rate of Growth ≡ Asymptotic Analysis • Using rate of growth as a measure to compare different functions implies comparing them asymptotically • i.e., as n  • If f(x) is growing faster than g(x), then f(x) always eventually becomes larger than g(x) in the limit • i.e., for large enough values of x Because we prefer the worst-case analysis !

  22. Complexity • Let us assume two algorithms A and B that solve the same class of problems. • The time complexity of A is 5,000n, T = f(n) = 5000*n • the one for B is 2nfor an input with nelements, T= g(n) = 2n • For n = 10, • A requires 5*104steps, • but B only 1024, • so B seems to be superior to A. • For n = 1000, • A requires 5*106steps, • while B requires 1.07*10301steps.

  23. Asymptotic Notation O notation: asymptotic “less than”: f(n) = O(g(n)) implies: f(n) “≤”c*g(n) in the limit, c is a constant In English: “ f(n) grows asymptoticallyno faster thang(n) ” c is a constant worst-case analysis

  24. Asymptotic Notation  notation: asymptotic “greater than”: f(n) = (g(n)) implies: f(n) “≥”c*g(n) in the limit , c is a constant In English: “ f(n) grows asymptotically faster thang(n) ” c is a constant best-case analysis *formal definition in CS477/677

  25. Asymptotic Notation  notation: asymptotic “equality”: f(n)= (g(n)) implies:f(n) “=”c*g(n) in the limit , c is a constant In English: “ f(n) grows asymptotically as fast asg(n) ” c is a constant tight bound analysis (best and worst cases are same) *formal definition in CS477/677

  26. Common Misunderstanding Worst case & Upper bound • Upper bound refers to a limit for the run-time of that algorithm. • Worst case refers to the worst inputamong the choices for possible inputs of a given size.

  27. Big O in practice • Figure outT=f(n): run-time (number of basic operations) required on an input of size n • Remove low-order terms

  28. More on big-O O(g(n)) can be related to a set of functions f(n) f(n) = O(g(n)) if “f(n)≤c*g(n)” Big-O notation provides a machine independent means for determining the efficiency of an algorithm.

  29. Names of Orders of Magnitude O(1) bounded (by a constant) time O(log2N) logarithmic time O(N) linear time O(N*log2N) N*log2N time O(N2) quadratic time O(N3)cubic time O(2N ) exponential time

  30. Constant Time Algorithms • An algorithm is O(1) when its running time is independent of the number of data items. The algorithm runs in constant time. The storing of the element involves a simple assignment statement and thus has efficiency O(1).

  31. Linear Time Algorithms • An algorithm is O(n) when its running time is proportional to the size of the list. • When the number of elements doubles, the number of operations doubles.

  32. Logarithmic Time Algorithms • The logarithm of n, base 2, is commonly used when analyzing computer algorithms. For example, sorting algorithms. Ex. log2(2) = 1 log2(75) = 6.2288 • When compared to the functions n and n2, the function log2n grows very slowly.

  33. How do we calculate T=f(n) for a program/algorithm? • Associate a "cost" with each statement • Find total number of times each statement is executed • Add up the costs

  34. Running Time Examples i = 0; while (i<N) { X=X+Y; // O(1) result = mystery(X); // O(N) i++; // O(1) } • The body of the while loop: O(N) • Loop is executed: N times Running time of the entire iteration? N x O(N) = O(N2)

  35. Running Time Examples (cont.’d) if (i<j) for ( i=0; i<N; i++ ) X = X+i; else X=0; O(N) O(1) Running time of the entire if-else statement? Max (O(N), O(1)) = O(N)

  36. Complexity Examples What does the following algorithm compute? returns the maximum difference between any two numbers in the input array # of Comparisons: n-1 + n-2 + n-3 + … + 1 = (n-1)n/2 = 0.5n2 - 0.5n Time complexity is O(n2) intwho_knows(int a[n]) { int m = 0; for{inti = 0; i<n; i++} for {int j = i+1; j<n; j++} if(abs(a[i] – a[j]) > m ) m = abs(a[i] – a[j]); return m; }

  37. Complexity Examples Another algorithm solving the same problem: # of Comparisons: 2n - 2 Time complexity is O(n). intmax_diff(int a[n]) { int min = a[0]; int max = a[0]; for{inti = 1; i<n; i++} { if(a[i] < min ) min = a[i]; else if(a[i] > max ) max = a[i]; } return max-min; }

  38. Running time of various statements

  39. Examples (cont.’d)

  40. Examples (cont.’d)

  41. Analyze the complexity of the following code segments

  42. Homework #2: Algorithm analysis • Already assigned on BB, due on 9/14/2014, 11:59PM

  43. Next class & Reading • Next class: ADTs of Lists, Stacks, and Queues • Book Chapter 3: “Lists, Stacks, and Queues”

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