Worst-case complexity
In computer science, the worst-case complexity (usually denoted in asymptotic notation) measures the resources (e.g. running time, memory) that an algorithm requires given an input of arbitrary size (commonly denoted as n or N). It gives an upper bound on the resources required by the algorithm.
In the case of running time, the worst-case time-complexity indicates the longest running time performed by an algorithm given any input of size n, and thus guarantees that the algorithm will finish in the indicated period of time. The order of growth (e.g. linear, logarithmic) of the worst-case complexity is commonly used to compare the efficiency of two algorithms.
The worst-case complexity of an algorithm should be contrasted with its average-case complexity, which is an average measure of the amount of resources the algorithm uses on a random input.
Definition
Given a model of computation and an algorithm A that halts on each input x, the mapping tA:{0, 1}*→N is called the time complexity of A if, for every x, A halts after exactly tA(x) steps.
Since we usually are interested in the dependence of the time complexity on different input length, abusing terminology, the time complexity is sometimes referred to the mapping TA:N→N, defined by TA(n):= maxx∈{0, 1}n{tA(x)}.
Similar definitions can be given for space complexity, randomness complexity, etc.
Examples
Consider performing insertion sort on n numbers on a random access machine. The best-case for the algorithm is when the numbers are already sorted, which takes O(n) steps to perform the task. However, the input in the worst-case for the algorithm is when the numbers are reverse sorted and it takes O(n2) steps to sort them; therefore the worst-case time-complexity of insertion sort is of O(n2).
See also
References
- Thomas H. Cormen, Charles E. Leiserson, Ronald L. Rivest, and Clifford Stein. Introduction to Algorithms, Second Edition. MIT Press and McGraw-Hill, 2001. ISBN 0-262-03293-7. Chapter 2.2: Analyzing algorithms, pp.25-27.
- Oded Goldreich. Computational Complexity: A Conceptual Perspective. Cambridge University Press, 2008. ISBN 0-521-88473-X, p.32.