The Self-Taught Computer Scientist
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- Log-Linear Complexity O( n log n ) Figure 1.4
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Linear Complexity O(n)
Figure 1.3: Linear complexity Chapter 1 What Is an Algorithm? 11 Log- Linear Time An algorithm that runs in log- linear time grows as a combination (multiplication) of logarithmic and linear time complexities. For example, a log- linear algorithm might evaluate an O(log n) operation n times. In big O notation, you express a log- linear algorithm as O(n log n). Log- linear algorithms often divide a data set into smaller parts and process each piece independently. For example, many of the more efficient sorting algorithms you will learn about later, such as merge sort, are log- linear. Figure 1.4 shows what a log- linear algorithm looks like when you plot it on a graph. As you can see, log- linear complexity is not as efficient as linear time. However, its complexity does not grow nearly as quickly as quadratic, which you will learn about next. Quadratic Time After log- linear, the next most efficient time complexity is quadratic time. An algorithm runs in quadratic time when its performance is directly proportional to the problem’s size squared. In big O notation, you express a quadratic algorithm as O( n**2). Here is an example of an algorithm with quadratic complexity: numbers = [1, 2, 3, 4, 5] for i in numbers: for j in numbers: x = i * j print(x) Number of Customers 0 0 5 10 15 20 25 30 5 10 15 20 25 30 Number of Steps Log-Linear Complexity O(n log n) Figure 1.4: Log- linear complexity Introduction to Algorithms 12 This algorithm multiplies every number in a list of numbers by every other number, stores the result in a variable, and prints it. In this case, n is the size of your numbers list. The equation for this algorithm’s time complexity is as follows: f(n) = 1 + n * n * (1 + 1) The (1 + 1) in the equation comes from the multiplication and print statement. You repeat the multiplication and print statement n * n times with your two nested for loops. You can simplify the equation to this: f(n) = 1 + (1 + 1) * n**2 which is the same as the following: f(n) = 1 + 2 * n**2 As you may have guessed, the n**2 part of the equation overshadows the rest, so in big O notation, the equation is as follows: O(n) = n**2 When you graph an algorithm with quadratic complexity, the number of steps increases sharply as the problem’s size increases (Figure 1.5). Number of Customers 0 0 5 10 15 20 25 30 5 10 15 20 25 30 Number of Steps Download 1.48 Mb. Do'stlaringiz bilan baham: 
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