Does an algorithm exist that finds the maximum of an unsorted array in O(log n) time?
This question is asked a lot (is this a popular CS homework question or something?) and the answer is always the same: no.
Think about it mathematically. Unless the array is sorted, there is nothing to "cut in half" to give you the
Read the question comments for a more in-depth discussion (which is probably way out of the question's scope anyhow).
It's not possible to do this in
O(log(N)). It is
O(N) in the best/worst/average case because one would need to visit every item in the array to determine if it is the larges one or not. Array is unsorted, which means you cannot cut corners.
Even in the case of parallelisation, this cannot be done in
O(N), because Big-O notation doesn't care about how many CPU one has or what is the frequency of each CPU. It is abstracted from this specifically to give crude estamate of the problem.
Parallelisation can be neglected because time spent dividing a job can be considered equal to the time of sequential execution. This is due to the reason of constants being disregarded. The following are all the same:
O(N) = O(Const * N) = O(N / Const) = O(N + Const) = O(N - Const)
From the other hand, in practise, divide-and-conquer parallel algorithms can give you some performance benefits, so it may run a little bit faster. Fortunately, Big-O doesn't deal with this fine-grained algorithmic complexity analysis.
Of course NOT . suppose that there's still an element which you haven't still compared it with any other element . so there is no guarantee that the element you haven't compared is not the maximum element
and suppose that your comparing graph (vertices for elements and edges for comparing ) has more than one component . in this case you must put an edge (in the best way between maximum of two components).we can see that at n-1 operation MUST be done
This is very old, but I don't agree with the answers given. YES, it can be done, with parallel hardware, in logarithmic time.
Time complexity would be:
O(log(n) * log(m))
n is the quantity of numbers to compare;
m is the size of each number.
However, hardware size would be:
O(n * m)
The algorithm would be:
Compare numbers in pairs. Time of this is
O(log(m)), and size is
O(n * m), using carry look-ahead comparators.
Use the result in 1 to multiplex both inputs of 1. Time of this is
O(1), and size is
O(n * m).
Now you have an array half the initial size; go to step 1. This loop is repeated
log(n)times, so total time is
O(log(n) * log(m)), and total size is
O(n * m).
Adding some more MUXes you can also keep track of the index of the largest number, if you need it, without increasing the complexity of the algorithm.