Chapter 2 Complexity Analysis

Chapter 2Complexity Analysis

Objectives Discuss the following topics: • Computational and Asymptotic Complexity • Big-O Notation • Properties of Big-O Notation • Ω and Θ Notations • Examples of Complexities • Finding Asymptotic Complexity: Examples • Amortized Complexity • The Best, Average, and Worst Cases • NP-Completeness

Computational and Asymptotic Complexity • Computational complexity measures the degree of difficulty of an algorithm • Indicates how much effort is needed to apply an algorithm or how costly it is • To evaluate an algorithm’s efficiency, use logical units that express a relationship such as: • The size n of a file or an array • The amount of time t required to process the data

Computational and Asymptotic Complexity (continued) • This measure of efficiency is called asymptotic complexity • It is used when disregarding certain terms of a function • To express the efficiency of an algorithm • When calculating a function is difficult or impossible and only approximations can be found f (n) = n2 + 100n + log10n + 1,000

Computational and Asymptotic Complexity (continued) Figure 2-1 The growth rate of all terms of function f (n) = n2 + 100n + log10n + 1,000

Big-O Notation • Introduced in 1894, the big-O notation specifies asymptotic complexity, which estimates the rate of function growth • Definition 1: f (n) is O(g(n)) if there exist positive numbers c and N such that f (n) ≤ cg(n) for all n ≥ N Figure 2-2 Different values of c and N for function f (n) = 2n2 + 3n + 1 = O(n2) calculated according to the definition of big-O

Big-O Notation (continued) Figure 2-3 Comparison of functions for different values of c and N from Figure 2-2

Properties of Big-O Notation • Fact 1(transitivity) If f (n) is O(g(n)) and g(n) is O(h(n)), then f(n) is O(h(n)) • Fact 2If f (n) is O(h(n)) and g(n) is O(h(n)), then f(n) + g(n) is O(h(n)) • Fact 3The function ankis O(nk)

Properties of Big-O Notation (continued) • Fact 4The function nkis O(nk+j) for any positive j • Fact 5If f(n) = cg(n), then f(n) is O(g(n)) • Fact 6The function loga n is O(logb n) for any positive numbers a and b ≠ 1 • Fact 7loga n is O(lg n) for any positive a ≠ 1, where lg n = log2n

Ω and Θ Notations • Big-O notation refers to the upper bounds of functions • There is a symmetrical definition for a lower bound in the definition of big-Ω • Definition 2: The function f(n) is Ω(g(n)) if there exist positive numbers c and N such that f(n) ≥ cg(n) for all n ≥ N

Ω and Θ Notations (continued) • The difference between this definition and the definition of big-O notation is the direction of the inequality • One definition can be turned into the other by replacing “≥” with “≤” • There is an interconnection between these two notations expressed by the equivalence f (n) is Ω(g(n)) iff g(n) is O(f (n)) (prove?)

Ω and Θ Notations (continued) • Definition 3: f(n) is Θ(g(n)) if there exist positive numbers c1, c2, and N such that c1g(n) ≤ f(n) ≤ c2g(n) for all n ≥ N • When applying any of these notations (big-O,Ω, and Θ), remember they are approximations that hide some detail that in many cases may be considered important

Examples of Complexities • Algorithms can be classified by their time or space complexities • An algorithm is called constantif its execution time remains the same for any number of elements • It is called quadraticif its execution time is O(n2)

Examples of Complexities (continued) Figure 2-4 Classes of algorithms and their execution times on a computer executing 1 million operations per second (1 sec = 106 μsec = 103 msec)

Examples of Complexities (continued) Figure 2-4 Classes of algorithms and their execution times on a computer executing 1 million operations per second (1 sec = 106 μsec = 103 msec)(continued)

Examples of Complexities (continued) Figure 2-5 Typical functions applied in big-O estimates

Finding Asymptotic Complexity: Examples • Asymptotic bounds are used to estimate the efficiency of algorithms by assessing the amount of time and memory needed to accomplish the task for which the algorithms were designed for (i = sum = 0; i < n; i++) sum += a[i] • Initialize two variables • Execute two assignments • Update sum • Update i Total 2+2n assignments for the complete execution Asymptotic complexity is O(n)

Finding Asymptotic Complexity: Examples • Printing sums of all the sub-arrays that begins with position 0 for (i = 0; i < n; i++) { for (j = 1, sum = a[0]; j <= i; j++) sum += a[j]; System.out.println("sumforsubarray0through"+i+" is" + sum); } 1+3n+ =1+3n+2(1+2+….n-1) =1+3n+n(n-1)=O(n)+ O(n2)= O(n2)

Examples Continued • Printing sums of numbers in the last five cells of the sub-arrays starting in position 0 for (i = 4; i < n; i++) { for (j = i-3, sum = a[i-4]; j <= i; j++) sum += a[j]; System.out.println ("sumforsubarray"+(i-4)+"through"+i+"is"+ sum); } • n-4 times for outer loop • For each i, inner loop executes only four times 1+8.(n-4)= O(n)

Finding Asymptotic Complexity: Examples • Finding the length of the longest sub-array with the numbers in increasing order • For example [1 2 5 ] in [1 8 1 2 5 0 11 12] for (i = 0, length = 1; i < n-1; i++) { for (i1 = i2 = k = i; k < n-1 && a[k] < a[k+1]; k++, i2++); if (length < i2 - i1 + 1) length = i2 - i1 + 1; System.out.println("thelengthofthelongest orderedsubarrayis"+length); }

If all numbers in the array are in decreasing order, the outer loop is executed n-1 times • But in each iteration, the inner loop executes just one time. The algorithm is O(n) • If the numbers are in increasing order, the outer loop is executed n- 1 times and the inner loop is executed n-1-i times for each i in {0,…, n-2}. The algorithm is O(n2)

Finding Asymptotic Complexity: Examples int binarySearch(int[] arr, int key) { int lo = 0, mid, hi = arr.length-1; while (lo <= hi) { mid = (lo + hi)/2; if (key < arr[mid]) hi = mid - 1; else if (arr[mid] < key) lo = mid + 1; else return mid; // success } return -1; // failure } • O(lg n)

The Best, Average, and Worst Cases • The worst case is when an algorithm requires a maximum number of steps • The best case is when the number of steps is the smallest • The average casefalls between these extremes Cavg = Σip(inputi)steps(inputi)

The average complexity is established by considering possible inputs to an algorithm, • determining the number of steps performed by the algorithm for each input, • adding the number of steps for all the inputs, and dividing by the number of inputs • This definition assumes that the probability of occurrence of each input is the same. It is not the case always. • The average complexity is defined as the average over the number of steps executed when processing each input weighted by the probability of occurrence of this input

Consider searching sequentially an unordered arrayto find a number • The best case is when the number is found in the first cell • The worst case is when the number is in the last cell or not in the array at all • The average case?

1 + 2 + … + n n n + 1 2 = • Assuming the probability distribution is uniform • The probability equals to 1/n for each position • To find a number in one try is 1/n • To find a number in two tries is 1/n • etc… • The average steps to find a number is

If the probabilities differ, the average case gives a different outcome • If the probability of finding a number in the first cell is ½ , the probability in the second cell is ¼ and the probability is the same for remaining cells = • the average steps 1 4(n - 2) 1 - ½ - ¼ n - 2

S1: factor out constant S2: separate summed terms S3: sum of constant S4: sum of k S5: sum of k squared S6: sum of 2^k S7: sum of k2^(k-1) Summation Formulas Let N > 0, let A, B, and C be constants, and let f and g be any functions. Then:

Logarithms Let b be a real number, b > 0 and b  1. Then, for any real number x > 0, the logarithm of x to base b is the power to which b must be raised to yield x. That is: For example: If the base is omitted, the standard convention in mathematics is that log base 10 is intended; in computer science the standard convention is that log base 2 is intended.

L9: L1: L2: L8: L3: L10: L4: L7: L5: L6: Logarithms Let a and b be real numbers, both positive and neither equal to 1. Let x > 0 and y > 0 be real numbers.

C1: C2: Limit of a Function Definition: Let f(x) be a function with domain (a, b) and let a < c < b. The limit of f(x) as x approaches c is L if, for every positive real number e, there is a positive real number d such that whenever |x-c| < d then |f(x) – L| < e. The definition being cumbersome, the following theorems on limits are useful. We assume f(x) is a function with domain as described above and that K is a constant. C3:

C4: C5: C6: Limit of a Function Here assume f(x) and g(x) are functions with domain as described above and that K is a constant, and that both the following limits exist (and are finite): Then: C7:

C8: C9: C10: Limit as x Approaches Infinity Definition: Let f(x) be a function with domain [0, ). The limit of f(x) as x approaches  is L if, for every positive real number e, there is a positive real number N such that whenever x > N then |f(x) – L| < e. The definition being cumbersome, the following theorems on limits are useful. We assume f(x) is a function with domain [0, ) and that K is a constant.

Limit of a Rational Function Given a rational function the last two rules are sufficient if a little algebra is employed: Divide by highest power of x from the denominator. Take limits term by term. Apply theorem C3.

C11: C12: Infinite Limits In some cases, the limit may be infinite. Mathematically, this means that the limit does not exist. C13: Example:

l'Hôpital's Rule In some cases, the reduction trick shown for rational functions does not apply: In such cases, l'Hôpital's Rule is often useful. If f(x) and g(x) are differentiable functions such that This also applies if the limit is 0. then:

l'Hôpital's Rule Examples Applying l'Hôpital's Rule: Another example: Recall that:

Mathematical Induction Mathematical induction is a technique for proving that a statement is true for all integers in the range from N0 to , where N0 is typically 0 or 1. First (or Weak) Principle of Mathematical Induction Let P(N) be a proposition regarding the integer N, and let S be the set of all integers k for which P(k) is true. If 1) N0 is in S, and 2) whenever N is in S then N+1 is also in S, then S contains all integers in the range [N0, ). To apply the PMI, we must first establish that a specific integer, N0, is in S (establishing the basis) and then we must establish that if a arbitrary integer, N  N0, is in S then its successor, N+1, is also in S.

Induction Example Theorem: For all integers n  1, n2+n is a multiple of 2. proof: Let S be the set of all integers for which n2+n is a multiple of 2. If n = 1, then n2+n = 2, which is obviously a multiple of 2. This establishes the basis, that 1 is in S. Now suppose that some integer k  1 is an element of S. Then k2+k is a multiple of 2. We need to show that k+1 is an element of S; in other words, we must show that (k+1)2+(k+1) is a multiple of 2. Performing simple algebra: (k+1)2+(k+1) = (k2 + 2k + 1) + (k + 1) = k2 + 3k + 2 Now we know k2+k is a multiple of 2, and the expression above can be grouped to show: (k+1)2+(k+1) = (k2 + k) + (2k + 2) = (k2 + k) + 2(k + 1) The last expression is the sum of two multiples of 2, so it's also a multiple of 2. Therefore, k+1 is an element of S. Therefore, by PMI, S contains all integers [1, ). QED

Inadequacy of the First Form of Induction Theorem: Every integer greater than 3 can be written as a sum of 2's and 5's. (That is, if N > 3, then there are nonnegative integers x and y such that N = 2x + 5y.) This is not (easily) provable using the First Principle of Induction. The problem is that the way to write N+1 in terms of 2's and 5's has little to do with the way N is written in terms of 2's and 5's. For example, if we know that N = 2x + 5y we can say that N + 1 = 2x + 5y + 1 = 2x + 5(y – 1) + 5 + 1 = 2(x + 3) + 5(y – 1) but we have no reason to believe that y – 1 is nonnegative. (Suppose for example that N is 9.)

"Strong" Form of Induction There is a second statement of induction, sometimes called the "strong" form, that is adequate to prove the result on the preceding slide: Second (or Strong) Principle of Mathematical Induction Let P(N) be a proposition regarding the integer N, and let S be the set of all integers k for which P(k) is true. If 1) N0 is in S, and 2) whenever N0 through N are in S then N+1 is also in S, then S contains all integers in the range [N0, ). Interestingly, the "strong" form of induction is logically equivalent to the "weak" form stated earlier; so in principle, anything that can be proved using the "strong" form can also be proved using the "weak" form.

Using the Second Form of Induction Theorem: Every integer greater than 3 can be written as a sum of 2's and 5's. proof: Let S be the set of all integers n > 3 for which n = 2x + 5y for some nonnegative integers x and y. If n = 4, then n = 2*2 + 5*0. If n = 5, then n = 2*0 + 5*1. This establishes the basis, that 4 and 5 are in S. Now suppose that all integers from 4 through k are elements of S, where k  5. We need to show that k+1 is an element of S; in other words, we must show that k+1 = 2r + 5s for some nonnegative integers r and s. Now k+1  6, so k-1  4. Therefore by our assumption, k-1 = 2x + 5y for some nonnegative integers x and y. Then, simple algebra yields that: k+1 = k-1 + 2 = 2x + 5y + 2 = 2(x+1) + 5y, whence k+1 is an element of S. Therefore, by the Second PMI, S contains all integers [4, ). QED

Amortized Complexity • Amortized analysis: • Analyzes sequences of operations • Can be used to find the average complexity of a worst case sequence of operations • By analyzing sequences of operations rather than isolated operations, amortized analysis takes into account interdependence between operations and their results

Amortized Complexity (continued) Worst case: C(op1, op2, op3, . . .) = Cworst(op1) + Cworst(op2) + Cworst(op3) + . . . Average case: C(op1, op2, op3, . . .) = Cavg(op1) + Cavg(op2) + Cavg(op3) + . . . Amortized: C(op1, op2, op3, . . .) = C(op1) + C(op2) + C(op3) + . . . Where C can be worst, average, or best case complexity

Amortized Complexity (continued) Figure 2-6 Estimating the amortized cost

NP-Completeness • A deterministicalgorithm is a uniquely defined (determined) sequence of steps for a particular input • There is only one way to determine the next step that the algorithm can make • A nondeterministic algorithm is an algorithm that can use a special operation that makes a guess when a decision is to be made

NP-Completeness (continued) • A nondeterministic algorithm is considered polynomial: its running time in the worst case is O(nk) for some k • Problems that can be solved with such algorithms are called tractableand the algorithms are considered efficient • A problem is called NP-completeif it is NP (it can be solved efficiently by a nondeterministic polynomial algorithm) and every NP problem can be polynomially reduced to this problem

NP-Completeness (continued) • The satisfiability problemconcerns Boolean expressions in conjunctive normal form (CNF)

Summary • Computational complexitymeasures the degree of difficulty of an algorithm. • This measure of efficiency is called asymptotic complexity. • To evaluate an algorithm’s efficiency, use logical units that express a relationship. • This measure of efficiency is called asymptotic complexity.

Summary (continued) • Introduced in 1894, the big-O notation specifies asymptotic complexity, which estimates the rate of function growth. • An algorithm is called constantif its execution time remains the same for any number of elements. • It is called quadraticif its execution time is O(n2). • Amortized analysis analyzes sequences of operations.

Chapter 2 Complexity Analysis